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The '''scientific method''' is how scientists investigate [[phenomenon|phenomena]] and acquire new [[knowledge]]. It is based on [[observable]], [[empirical]], measurable evidence. Scientists propose [[hypothesis|hypotheses]] to explain [[phenomena]], and test those hypotheses by examining the evidence from [[experiment]]al [[research|studies]]. Scientists also formulate [[Theory#Science|theories]] that encompass whole domains of inquiry and bind hypotheses together into logically coherent wholes.
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<blockquote>  
<onlyinclude>{{Image|Hume.jpg|right|300px|Statue of [[David Hume]]. ''"Man is a reasonable being; and as such, receives from science his proper food and nourishment: But so narrow are the bounds of human understanding, that little satisfaction can be hoped for in this particular..."''
''"Science is a way of thinking much more than it is a body of knowledge." '' ([[Carl Sagan]]<ref>Sagan C. The fine art of baloney detection. Parade Magazine, p 12­13, Feb 1, 1987.</ref>).
Hume recognised clearly the difficulties in gaining a general understanding merely by accumulating observations.}}
</blockquote>
Scientists use a '''scientific method''' to investigate phenomena and acquire [[knowledge]]. They base the method on verifiable observation &mdash; i.e., on replicable [[empirical]] evidence rather than on pure logic or supposition &mdash; and on the [[reasoning|principles of reasoning]].<ref>[[Isaac Newton]] (1643-1727) [http://www.fordham.edu/halsall/mod/newton-princ.html The Rules of Reasoning in Philosophy] Excerpts in: The Mathematical Principles of Natural Philosophy. Source:  [http://www.fordham.edu/halsall/mod/modsbook.html Modern History Sourcebook]</ref> <ref>[http://www.archive.org/details/newtonspmathema00newtrich Full-Text: Newton's Principia: The Mathematical Principles of Natural Philosophy (c1846), including BOOK III. RULES OF REASONING IN PHILOSOPHY]</ref> Scientists propose explanations &mdash; called [[hypothesis|hypotheses]] &mdash; for their observed phenomena, and perform experiments to determine whether the results accord with (support) the hypotheses or falsify them. They also formulate [[Theory#Science|theories]] that encompass whole domains of inquiry, and which bind supported hypotheses together into logically coherent wholes. They refer to theories sometimes as ‘models’, which often have a mathematical or computational basis.<ref name=leng2008>Leng G, MacGregor DJ. (2008) [http://dx.doi.org/10.1111/j.1365-2826.2008.01722.x Mathematical Modelling in Neuroendocrinology]. ''Journal of Neuroendocrinology: From Molecular to Translational Neurobiology'' 20:713-718.
*'''<u>Excerpt:</u>''' Our science is not only about facts, but also about explanations; rational  accounts of phenomena, embedded in a framework of theory, which include a wide range of observations and which are predictive of behaviour in circumstances as yet untested. We all seek to explain the world of observations using a set of logically interacting components, and we all simplify by recognising that some observations are important while others can be reasonably neglected. Formulating such explanations mathematically is a natural ambition, because this ensures their logical consistency, and makes them open to structured analysis; it is a stringent test of their intellectual coherence.</ref> <ref name=mathscope>Citizendium Collaborators. (2009) [http://en.citizendium.org/wiki/Biology%27s_next_microscope:_Mathematics Biology’s Next Microscope: Mathematics.] Citizendium Free Online Encyclopedia.
*'''<u>Excerpt:</u>''' Mathematics broadly interpreted is a more general microscope. It can reveal otherwise invisible worlds in all kinds of data, not only optical….Charles Darwin was right when he wrote that people with an understanding “of the great leading principles of mathematics... seem to have an extra sense”….Today’s biologists increasingly recognize that appropriate mathematics can help interpret any kind of data. In this sense, mathematics is biology’s next microscope, only better.</ref></onlyinclude>
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==Elements of scientific method==
__TOC__
According to [[Charles Darwin]] ,
<br>
:''". . .science consists in grouping facts so that general laws or conclusions may be drawn from them."''


This simple account begs many questions. What do we mean by ‘facts’?  How much can we trust our senses to enable us to believe that what we see is true?  How exactly do scientists ‘group’ facts?  How do they select which facts to pay attention to, and is it even possible to do this in an objective way? And having done this, how exactly do they go about drawing any broader conclusions from the facts that they assemble? How can we know ''more'' than we observe directly? The English philosopher, [[Francis Bacon]] is sometimes credited as the leader of a scientific revolution with his 'observation and experimentation' theory, the template of the scientific method as conducted ever since. He recognised clearly that interpreting nature needs more than observation and reason:
==Components of the scientific method==
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|Science is said to proceed on two legs, one of theory (or, loosely, of deduction) and the other of observation and experiment (or induction). Its progress, however, is less often a commanding stride than a kind of halting stagger — more like the path of the wandering minstrel than the straight-ruled trajectory of a military marching band. The development of science is influenced by intellectual fashions, is frequently dependent upon the growth of technology, and in any case, seldom can be planned far in advance, since its destination is usually unknown.
:&mdash;Timothy Ferris, ''Coming of Age in the Milky Way'' (1988)<ref>Ferris T. (1988) ''Coming of Age in the Milky Way''. New York: Morrow, ISBN 0688058892. | [http://books.google.com/books?id=k0vCHGD5Y00C&printsec=frontcover#v=onepage&q=trajectory&f=false Google Books preview, 2003 edition].</ref>
|}
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<!--<blockquote>''"Science is said to proceed on two legs, one of theory (or, loosely, of deduction) and the other of observation and experiment (or induction). Its progress, however, is less often a commanding stride than a kind of halting stagger — more like the path of the wandering minstrel than the straight-ruled trajectory of a military marching band. The development of science is influenced by intellectual fashions, is frequently dependent upon the growth of technology, and in any case, seldom can be planned far in advance, since its destination is usually unknown."''  Timothy Ferris, ''Coming of Age in the Milky Way'' (1988)</blockquote>-->
{{Image|Research cycle.png|right|300px|A simplified depiction of the cyclic nature of scientific research: An initial observation triggers an idea that is being developed into a hypothesis which &mdash; if funds, equipment and the necessary expertise are available &mdash; may lead to experimental data (or other forms of verifiable evidence) that can support or contradict the hypothesis or other existing theoretical descriptions of the system at hand, which in turn can trigger independent replication or falsification of this particular experiment if the relevant information are made available to other researchers. Traditionally, this publication step would be achieved solely via articles in toll-access [[scientific journal]]s but initiatives like [[Open access]], [[Open Source]] and [[Open Data]] are increasingly making all these individual steps public, which is facilitated through the use of [[Web 2.0]] technologies in what has come to be called [[Science 2.0]].}}


:''...But the universe to the eye of the human understanding is framed like a labyrinth, presenting as it does on every side so many ambiguities of way, such deceitful resemblances of objects and signs, natures so irregular in their lines and so knotted and entangled. And then the way is still to be made by the uncertain light of the sense, sometimes shining out, sometimes clouded over, through the woods of experience and particulars; while those who offer themselves for guides are (as was said) themselves also puzzled, and increase the number of errors and wanderers. In circumstances so difficult neither the natural force of man's judgement nor even any accidental felicity offers any chance of success. No excellence of wit, no repetition of chance experiments, can overcome such difficulties as these. Our steps must be guided by a clue...'' ([[Francis Bacon]]) <ref>from ''Preface to The Great Instauration; 4.18'' quoted in Pesic P (2000)The Clue to the labyrinth: Francis Bacon and the decryption of nature ''Cryptologia''
Generally accepted components of a scientific method are:
[http://www.sirbacon.org/pesic.htm]</ref>
* ''Observation.''<ref> According to the [[logical positivist]] philosopher [[Rudolf Carnap]], philosophers and scientists use the term 'observable' in different ways. To philosophers, 'observable' applies to properties that are directly perceived by the senses, such as "blue", "hard" and "hot". To scientists, the word includes anything  that can be measured relatively simply and directly. Carnap R (1966)[http://www.marxists.org/reference/subject/philosophy/works/ge/carnap.htm Theories and Nonobservables] from ''Philosophical Foundations of Physics'' Basic Books, ASIN B0000CN9NI </ref> Observations do not just await discovery, rather they often result from active exploration, questioning, sharing ideas and information among scientists, thinking creatively. Moreover, according to most current views, observations do not come into view wholly independently of some predetermined or preconceived theory; scientists struggle to keep their preconceptions and presuppositions out of the picture.<ref>[http://www.galilean-library.org/theory.html Theory-ladenness] by Paul Newall at The Galilean Library</ref><ref>Darwin CR. (1861) [http://www.darwinproject.ac.uk/darwinletters/calendar/entry-3257.html Letter 3257 — Darwin, C. R. to Fawcett, Henry, 18 Sept (1861)]
:*'''Note:''' [[Charles Darwin|Darwin]] understood the point.  Excerpt from the letter to Fawcett: “About thirty years ago there was much talk that geologists ought only to observe and not theorise; and I well remember some one saying that at this rate a man might as well go into a gravel-pit and count the pebbles and describe the colours. ''How odd it is that anyone should not see that all observation must be for or against some view if it is to be of any service!”''” <nowiki>[</nowiki>Emphasis added<nowiki>]</nowiki></ref> Sometimes "believing is seeing".
*''Hypothesis.'' Hypotheses are general statements, formulated as plausible conjectures to explain existing observations and predict future observations.
*''Experiment.''<ref> For [[Aristotle]], science was the product of reason applied to careful observations; [[Galileo Galilei]] by contrast used experiments as a way to interrogate Nature.</ref> An experiment is a procedure carried out under controlled conditions to discover an unknown effect; to provide confirming or disconforming evidence for a hypothesis, often based on whether a prediction of the hypothesis ensues; or, to illustrate an accepted theory. Not all areas of science involve direct experimentation; as an example for [[data-driven research]], the [[Human Genome Project]] largely involved (highly technical) interpretation of gene sequences, but the data were obtained by experimental investigation.
* ''Theory.'' A [[Theoretical biology|theory]] incorporates a set of supported hypotheses into a logical framework that overall explains the phenomenon studied. Not all of the statements of a theory are necessarily open to experimental testing, but many are expected to be for a theory to be considered scientific.  The scientific method usually involves further testing of its accepted satisfactory overall explanation of a phenomenon, as natural phenomena usually have more observable features than the theorist knows at the time the theory hatches.  A good theory will make accurate predictions about the behavioral aspects of the phenomenon studied, suggesting experiments to test its overall explanatory power.
* ''Prediction.'' A prediction is a logical deduction from a hypothesis (or theory) by which the hypothesis (or theory) can be tested experimentally.
* ''Testing.'' A 'test' of a hypothesis is an experiment, the results of which might falsify (disprove) the hypothesis; if the test does not falsify the hypothesis, the test is said to support ('confirm') the hypothesis. The same holds for testing theories.
* ''Causal explanation.''  Satisfactory explanations are often regarded as those that establish a cause-effect relationship. However, many scientists argue that concepts of causality are not obligatory to science, but are well-defined only under particular conditions.<ref>Dowe, Phil. (Fall 2008 Edition) [http://plato.stanford.edu/archives/fall2008/entries/causation-process/ Causal Processes.] ''The Stanford Encyclopedia of Philosophy. Edward N. Zalta.</ref> <ref>Woodward, James. (Spring 2009 Edition) [http://plato.stanford.edu/archives/spr2009/entries/scientific-explanation/ Scientific Explanation.] ''The Stanford Encyclopedia of Philosophy. Edward N. Zalta (ed.).</ref>  
* ''Skeptical open mindedness.'' Progress in extending existing theoretical frameworks is made possible by a scientific culture that encourages challenges to existing theory, while also demanding that far-reaching conjectures are validated by exceptional evidence.<ref>'''<u>Note:</u>''' Regarding 'skeptical open mindedness', to paraphrase space engineer, James Oberg, open mindedness confers virtue unless it so opens the mind that one's brains fall out. (Cited by Carl Sagan, in ''The Demon-Haunted World: Science as a Candle in the Dark.'' Ballantine Books: New York, 1997. Preview Sagan's book at Google Books [http://books.google.com/books?id=q_Fp3tjPnkwC here].)
*'''<u>Excerpt:</u>''' Keeping an open mind is a virtue — but, as the space engineer James Oberg once said, not so open that your brains fall out. Of course we must be willing to change our minds when warranted by new evidence. But the evidence must be strong. Not all claims to knowledge have equal merit. (Page 187)</ref>


We live in a world that is not directly understandable. We sometimes disagree about the ‘[[fact]]s’ we see around us, and some things in the world are at odds with our understanding. What we call the “scientific method” is an account of how scientists attempt to reach agreement and understanding, to provide explanations that will be consistent with the world and will withstand critical logical and experimental scrutiny. A "perfect" scientific method might work in such a way that its [[rationality|rational]] application would always result in agreement and understanding; a perfect method would arguably be [[algorithm|algorithmic]], and not leave any room for rational agents to disagree. [[Logical positivism|Logical Positivist]], [[empiricism|empiricist]], [[falsifiability|falsificationist]], and other theories have claimed to give a definitive account of the logic of science, but each has been criticised.  
==Philosophy of scientific methods==
<blockquote>''If the purpose of scientific methodology is to prescribe or expound a system of enquiry or even a code of practice for scientific behavior, then scientists seem to be able to get on very well without it. Most scientists receive no tuition in scientific method, but those who have been instructed perform no better as scientists than those who have not. Of what other branch of learning can it be said that it gives its proficients no advantage; that it need not be taught or, if taught, need not be learned?'' [[Peter Medawar]]<ref>Medawar P (1982) ''Pluto's Republic'', Oxford University Press ISBN 0192830392; read [http://www.the-rathouse.com/Medawar_PlutoRepublic.html a review here]</ref></blockquote>
{|align="left" cellpadding="10" style="background:lightgray; width:25%; border: 1px solid #aaa; margin:20px; font-size: 93%; font-family: Gill Sans MT;"
| Evolutionary processes and, in general, scientific explanations of the world are often in contrast with the immediate and simple explanations that our brain gives of reality (e.g. the sun seems to turn around the earth, the earth seems to be flat), and are influenced by what Francis Bacon called "idola"[<ref name=hall>Hall MP. [http://www.sirbacon.org/links/4idols.htm The Four Idols of Francis Bacon: The New Instrument of Knowledge].
*<font face="Gill Sans MT">"In the Novum Organum (the new instrumentality for the acquisition of knowledge) Francis Bacon classified the intellectual fallacies of his time under four headings which he called idols. He distinguished them as idols of the Tribe, idols of the Cave, idols of the Marketplace and idols of the Theater…An idol is an image, in this case held in the mind, which receives veneration but is without substance in itself. Bacon did not regard idols as symbols, but rather as fixations."</font></ref>] (false notions or tendencies which distort the truth [<ref>Fantini F. (2005) Didattica dell'evoluzione. In Evoluzione tra ricerca e didattica, XIV – Special number Edited by: Associazione Nazionale Insegnanti di Scienze Naturali. Agnano Pisano: Stamperia Editoriale Pisana; 2005:203-209.</ref>]).<ref name=guidetti>Guidetti R, Baraldi L, Calzolai C, Pini L, Veronesi P, Pederzoli A. (2007)  [http://www.biomedcentral.com/1471-2148/7/S2/S Fantastic animals as an experimental model to teach animal adaptation]. ''BMC Evolutionary Biology'' 7(Suppl 2):S13 doi: 10.1186/1471-2148-7-S2-S13.</ref>
|}
Non-scientists often represent science as a dry, mechanical activity, involving accumulating large numbers of facts, whether by simple observations or by technologically ingenious means. Indeed, this ''is'' an important part of science, and technological advances in our ability to interrogate the world have played an essential part in the advance of science: we need only consider how the [[light microscope]], then the [[electron microscope]], and now the [[scanning tunneling microscope]]<ref>[http://nobelprize.org/educational_games/physics/microscopes/scanning/index.html Scanning Tunneling Microscope] at the Nobel Foundation's website</ref> and [[two-photon laser scanning confocal microscopy]] have radically changed our understanding of the world. However, observations, things that we might sometimes call 'facts', are just the beginning. Thus, according to [[Charles Darwin]] (1809-1882), "science consists in grouping facts so that general laws or conclusions may be drawn from them."<ref> From the autobiography of Charles Darwin, [http://www.worldwideschool.org/library/books/hst/european/TheAutobiographyofCharlesDarwin/chap2.html available online].</ref>


The success of science, as measured by the technological achievements that have progressively changed our world, have led many to the conclusion that this must reflect the success of rules that scientists follow in their research. However, not all philosophers accept this conclusion; notably, the philosopher  Paul [[Feyerabend]] denied that science is genuinely a methodological process. In his book ''[[Against Method]]'' he argued that scientific progress is ''not'' the result of applying any particular rules. Instead, he concluded almost that "anything goes", in that for any particular ‘rule’ there are abundant examples of successful science that have proceeded in a way that seems to contradict it. <ref> [[Paul Feyerabend|Feyerabend PK]] (1975) ''Against Method, Outline of an Anarchistic Theory of Knowledge'' Reprinted, Verso, London, UK, 1978</ref> To Feyeraband, there is no fundamental difference between science and other areas of human activity characterised by reasoned thought. A similar sentiment was expressed by  [[T.H. Huxley]] in  1863:  "The method of scientific investigation is nothing but the expression of the necessary mode or working of the human mind. It is simply the mode at which all phenomena are reasoned about, rendered precise and exact."
But what exactly do we mean by ‘facts’? We sometimes disagree about the ‘facts’ we see around us, and some things in the world are at odds with our understanding. How much can we trust our senses to allow us to believe what we see? How do scientists ‘group’ facts? How do they choose which facts to attend to, and is it possible to do this in an objective way? And having done this, how do they draw any broader conclusions? Most importantly, how can we ever know ''more'' than we observe directly? We live in a world that is not directly understandable: we all ''interpret'' everything that we see and hear and feel, and to make sense of what our senses tell us we need to construct ''explanations'', or formulate theories. Our explanations identify some things as important and other things as irrelevant; they lead us to pay attention to some things and not others, and they lead us to expect some things to happen and not others &mdash; they lead, in other words, to predictions.  


Nevertheless, in the Daubert v. Merrell Dow Pharmaceuticals, Inc. [509 U.S. 579 (1993)] decision, the U.S. Supreme Court accorded a legal status to ‘The Scientific Method ‘, in ruling that "… to qualify as ’scientific knowledge’ an inference or assertion must be derived by the scientific method. Proposed testimony must be supported by appropriate validation - i.e., ‘good grounds,’ based on what is known." The Court also stated that "A new theory or explanation must generally survive a period of testing, review, and refinement before achieving scientific acceptance. This process does not merely reflect the scientific method, it is the scientific method."
Nothing about this is unique to science, but scientists attempt to harness these universal elements of reasoning in a consistent, systematic and rigorous manner, and in a way that minimizes bias. What we call the 'scientific method' is an account of how scientists gather and report observations in ways that will be understood by other scientists and accepted as valid evidence, and how they construct explanations that are consistent with the world, and that can withstand logical and experimental scrutiny and provide the foundations for further increases in understanding.


==Hypotheses and theories==
For many, the scientific approach begins with an attitude of skepticism &mdash; a willingness to question accepted beliefs, expressed by [[René Descartes]] in 1637 as a determination "never to accept anything for true which I did not clearly know to be such". The English philosopher [[Francis Bacon]] (1561-1626), often described as the pioneer of the modern scientific method, proposed that scientists should "empty their minds" of self-evident truths and, by observation and experimentation, should draw general conclusions by a process known as [[induction (philosophy)|induction]].<ref> [[Francis Bacon|Bacon, Francis]] (1620) ''[[Novum Organum]] (The New Organon)''</ref> Bacon described many of the commonly accepted principles of scientific method, but recognised that to interpret nature, something more than observation and reason is needed:
Hypotheses and theories play a central role in science; the idea that any observer can study the world except through the spectacles of his or her preconceptions and expectations is not sustainable. As these preconceptions change with progressively changing understanding of the world, the nature of science itself changes, and what was once considered conventionally scientific no longer seems so in retrospect.  
:''...the universe to the eye of the human understanding is framed like a labyrinth, presenting as it does on every side so many ambiguities of way, such deceitful resemblances of objects and signs, natures so irregular in their lines and so knotted and entangled. ... No excellence of wit, no repetition of chance experiments, can overcome such difficulties as these. Our steps must be guided by a clue...''<ref>from ''Preface to The Great Instauration; 4.18'' quoted in Pesic P (2000) The Clue to the labyrinth: Francis Bacon and the decryption of nature [http://www.sirbacon.org/pesic.htm ''Cryptologia'']. Francis Bacon should not be confused with [[Roger Bacon]] (ca 1214-1294), a Franciscan friar who also has claims to be a pioneer of observation and experiment, and who was imprisoned when his work challenged the dogma of the Church.</ref>


A [[hypothesis]] is a proposed explanation of a phenomenon. It is an “inspired guess”, a “bold speculation” , embedded in current understanding yet going beyond that to assert something that we do not know for sure as a way of explaining something not otherwise accounted for. Scientists use many different means to generate hypotheses including their own creative imagination, ideas from other fields, [[induction (philosophy)|induction]], [[Bayesian inference]]. [[Charles Sanders Peirce]] described the incipient stages of [[inquiry]], instigated by the "irritation of doubt" to venture a plausible guess, as ''[[Inquiry#Abduction|abductive reasoning]]''. The history of science is filled with stories of scientists claiming a "flash of inspiration", or a hunch, which then motivated them to look for evidence to support or refute their idea. [[Michael Polanyi]] made such creativity the centrepiece of his discussion of methodology.  
The 'something more' that is needed comes from imagination and intuition, guided by reason and understanding. Scientists make ambitious 'leaps' to envisage possible explanations that make sense of what we see. Classically, the scientific method has thus been broken into basic facets that start with ''observations'' of nature and how it behaves and then making a ''prediction'' about how it might behave under different circumstances. Scientists propose a ''hypothesis'' and, by ''experiments'' test it by eliminating any plausible alternatives in a process of ''falsification''. Other scientists join in the process of hypothesis testing, while at the same time developing new hypotheses that seek to explain more and more, thereby building a foundation of knowledge that they call science. However all of this is guided by theory &mdash; a framework of accepted knowledge and understanding that guides our choice of questions to ask, guides our choices about how to go about answering those question, and guides our interpretation of the results of those experiments. This theoretical framework that captures what we think we already know is what provides the clues to know more. When we are mistaken in what we think we know, however, everything that we build on those foundations becomes unsafe, and when a new theory emerges much of what we thought we had learned has to be interpreted afresh. New theories are therefore embraced only with reluctance, only as a last resort, because of the inevitable disruption that entails.


The philosopher  [[Karl Popper]] , in a book that Sir Peter Medawar called one of the most important documents of the 20th century, argued forcefully that argued that  
==Hypotheses==
<blockquote>''The man of science must work with method. Science is built up of facts, as a house is built of stones; but an accumulation of facts is no more a science than a heap of stones is a house. ''[[Henri Poincaré]], mathematician and philosopher (1854-1912)<ref> Henri Poincaré (1905). [http://www.brocku.ca/MeadProject/Poincare/Poincare_1905_toc.html Science and Hypothesis]. London: Walter Scott Publishing.</ref></blockquote>
The philosopher [[Karl Popper]] (1902-1994), in ''The Logic of Scientific Discovery'' <ref> Popper K (1959) ''The Logic of Scientific Discovery'' (Translation of ''Logik der Forschung''). The Nobel prize winner Sir Peter Medawar called this book  "one of the most important documents of the 20th century" </ref> argued that the 'Baconian' process of induction &mdash; of gathering facts, considering them, and inferring general laws &mdash; is logically unsound, as many mutually inconsistent hypotheses might be consistent with any given facts.<ref>{{cite web |url=http://plato.stanford.edu/entries/induction-problem/ |title=The Problem of Induction (Stanford Encyclopedia of Philosophy) |accessdate=2007-11-16 |author=Vickers, J |date=2006 |publisher=Stanford Encyclopedia of Philosophy}}</ref> Rather, Popper argued that the good scientist begins with a bold speculation, a hypothesis, from which he logically deduces predictions that can be tested by experiments. Experiments are not designed to confirm or verify the hypothesis, quite the contrary, they are designed to ''test'' the hypothesis, by attempting to disprove it. He argued that this 'hypothetico-deductive' method was the only sound way by which science makes progress, and concluded that for a proposition to be considered scientific, it must, at least in principle, be possible to make an observation that would show it to be false. Otherwise, the proposition has, as Popper put it, no connection with the real world.


==Responses to Popper: Thomas Kuhn and the Science Wars==
Popper's views were in marked contrast to those of his contemporary, [[Thomas Kuhn]] (1922-1996). Kuhn's own book ''The Structure of Scientific Revolutions'' was as influential as Popper's, but its message was very different. Kuhn analysed 'scientific revolutions' &mdash; times in the history of science when one dominant theory was replaced by another, such as the replacement of [[Ptolemy]]'s geocentric model of the Universe with the [[Copernicus| Copernican]] heliocentric model, and the replacement of Newtonian laws of motion with [[Albert Einstein|Einstein]]'s theory of [[Relativity]].


He argued that the essential quality of a good hypothesis is that it must be [[falsifiable]]; it must be challengeable by experiments, and he argued that science is this process of challenging hypotheses by experiments, and that progress is made when a hypothesis resists determined attempts at disproof, and becomes provisionally accepted as a valuable tool for adding to our understanding. Conversely, he argued that a proposition or theory cannot be called scientific if it does not admit the possibility of being shown false. It must, at least in principle, be possible to make an observation that would show the proposition to be false, otherwise the proposition is vacuous, with, as Popper put it, no connection with the real world. For Popper therefore, explanations without any predictive content, and he argued that the explanations of Freudian [[psychoanalysis]], those of [[Marxism]], and those of [[astrology]], were all examples of ‘empty’ unscientific theories.
While in many respects, Popper seemed to be making flat assertions about 'good science', Kuhn attempted to work as a sociologist, and to report what scientists actually did. At least initially in his career, he believed in some form of scientific progress.  


For Popper, a theory was the context within which hypotheses are developed, and which determined which things were important to investigate and which were not. The theory encompasses the preconceptions by which the world is viewed, and defines the ways we study it and understand it. A theory thus has a profound importance, without a theory no science is possible. He thus recognised that you do not discard a theory lightly, and that a theory might be inconsistent with many known facts (anomalies). However, the recognition of anomalies drives scientists to elaborate or adjust the theory, and if the anomalies continue to accumulate, will drive them to develop alternative theories. He also explained that theories always contain many elements that are not falsifiable, but he argued that these should be kept to a minimum, and that the content of a theory should be judged by the extent to which it inspired testable hypotheses (although this is certainly not his only criterion). Scientists also seek theories that are "[[elegant]]" or "[[beautiful]]"; these terms are subjective and hard to define, but they express the scientists expectation that a theory should yield clear, simple explanations of complex phenomena, that are intellectually satisfying in the sense of appearing to be logically coherent, rich in content, and involving no miracles or other supernatural devices.
Kuhn divided scientific development (to avoid the word 'progress') into two phases, times of [[normal science]] and times of [[paradigm shift]]. A [[paradigm]] is a logically consistent set of ideas that guides and constrains the work that scientists do. Scientific research conducted in accordance with a dominant paradigm is called ''normal science''. A ''paradigm shift'' occurs when a radical change occurs in the fundamental beliefs scientists hold about their field of study.  


Kuhn concluded that falsifiability had played almost no role in scientific revolutions. He argued that scientists working in a field resist the alternative interpretations of 'outsiders', and tenaciously defend their world view by continually elaborating their shared theory; "normal science often suppresses fundamental novelties because they are necessarily subversive of its basic commitments".


Popper thus argued that progress in science depends upon attempted falsification of hypotheses, and that most progress came by success in falsifying them; disproof is logically sound, support by induction is logically unsound. "Verifiability" in Popper's view was not the object or intent of science, just a weak by-product of a failed attempt at falsification.
According to Kuhn, most progress is made in a scientific field when one theory is dominant. Progress occurs by the "puzzle solving" of scientists who are not trying to challenge the accepted theory, but are trying to extend its scope and explanatory power, bringing theory and fact into closer agreement by a "strenuous and devoted attempt to force nature into the conceptual boxes supplied by professional education".<ref>
Kuhn TS (1961) The Function of Measurement in Modern Physical Science ''ISIS'' 52:161–193
* Kuhn TS (1962)''The Structure of Scientific Revolutions'' University of Chicago Press, Chicago, IL. 2nd edition 1970, 3rd edition 1996
* Kuhn TS (1977) ''The Essential Tension, Selected Studies in Scientific Tradition and Change'' University of Chicago Press, Chicago, IL
*A [http://www.des.emory.edu/mfp/kuhnsyn.html Synopsis] from the original by Professor Frank Pajares, From the Philosopher's Web Magazine
*Moloney DP (2000) ''First Things'' '''101'''[http://www.firstthings.com/ftissues/ft0003/articles/kuhn.html 53-5]</ref>


The historian of science [[Thomas Kuhn]] maintains that the "route from theory to measurement can almost never be travelled backward"; which theory is tested is dictated by the nature of the theory itself. This led Kuhn to argue that "once it has been adopted by a profession ... no theory is recognized to be testable by any quantitative tests that it has not already passed".<ref>
After the publication of 'The Structure of Scientific Revolutions' in 1962, Kuhn's revolution expanded. In the 1960s and 1970s, the academy (particularly in America) was in ferment. The development of radical and Marxist theory combined with political frustrations, and gave rise to a generation of academics who were deeply dissatisfied with the central narratives of American life, including scientific progress. Many of these academics latched on to Kuhn's ideas (and sometimes just his slogans) as a natural fit with their own ideas.
[[Thomas Kuhn|Kuhn TS]] (1961) The Function of Measurement in Modern Physical Science ''ISIS'' 52:161–193
* Kuhn TS (1962)''The Structure of Scientific Revolutions'', University of Chicago Press, Chicago, IL, 1962. 2nd edition 1970.  3rd edition 1996.
* Kuhn TS (1977) ''The Essential Tension, Selected Studies in Scientific Tradition and Change'', University of Chicago Press, Chicago, IL</ref>


This frustration with mainstream science took a series of forms. In the 1970s, the conflict began with early skirmishes about [[intelligence testing]] and the small-scale, though ferocious, battle over [[sociobiology]]. (It is worth noting that the sociobiology affair remained primarily a dispute within science) The partisans of the sociobiology debate continued their struggle into the 1980s. In the 1990s, scholars from the humanities and social sciences launched an assault on the central beliefs of science in what came to be known, somewhat hyperbolically, as the [[science wars]].


==Experiments and observations==
==Theories==
[[Werner Heisenberg]] in a quote that he attributed to [[Albert Einstein]] , stated [Heisenberg 1971]:
{|align="right" cellpadding="10" style="background:lightgray; width:35%; border: 1px solid #aaa; margin:20px; font-size: 93%; font-family: Gill Sans MT;"
: ''The phenomenon under observation produces certain events in our measuring apparatus. As a result, further processes take place in the apparatus, which eventually and by complicated paths produce sense impressions and help us to fix the effects in our consciousness. Along this whole path—from the phenomenon to its fixation in our consciousness—we must be able to tell how nature functions, must know the natural laws at least in practical terms, before we can claim to have observed anything at all. Only theory, that is, knowledge of natural laws, enables us to deduce the underlying phenomena from our sense impressions.''
|The three [[Laws of Thermodynamics]] can be expressed in many different ways<ref>these examples are given as on a [http://www.grc.nasa.gov/WWW/K-12/airplane/thermo.html NASA web site]</ref>
For much of the 20th century, the dominant approach to science has been [[reductionism]] the attempt to explain all phenomena in terms of basic laws of physics and chemistry. This driving principle of scientific methodology has ancient roots - Francis Bacon (1561-1626) quotes Aristotle favourably as declaring "That the nature of everything is
|-
best seen in his smallest portions." <ref>[[Francis Bacon]] 'The Advancement of Learning' [http://www.gutenberg.org/etext/5500]</ref>
|[[Zeroeth Law]]:&nbsp;When two objects are separately in thermodynamic equilibrium with a third object, they are in equilibrium with each other.
In many fields, however, reductionist explanations of complex phenomena are impractical, and all explanations involve 'high level' concepts. Nevertheless, the reductionist belief has been that these high level concepts are all ultimately reducible to physics and chemistry, and that the role of science is to progressively explain high level concepts by concepts closer and closer to the basic physics and chemistry. For example, to explain the behaviour of individuals we might refer to motivational states such as [[hunger]] or [[stress]] or [[anxiety]]. We believe that these reflect features of the activity of the brain that are still poorly understood, but can investigate the brain areas that house these motivational drives, calling them, for example, “hunger centres”, These centres each involve many [[neural networks]] – interconnected nerve cells, and the functions of each network we can again probe in more detail. These networks in turn are composed of specialised [[neuron]]s, whose behaviour can be analysed individually. These specialised nerve cells have distinctive properties that are the product of a genetic program that is activated in development – and so reducible to [[molecular biology]]. However, while behaviour is in this sense reducible to basic elements, explaining behaviour of an individual in terms of these basic elements has little predictive value, because the uncertainties in our understanding are too great, so explanations of behaviour still largely depend upon the high level constructs.
|-
Historically, the converse philosophical position to reductionism has taken many names, but the clearest debate was between “[[vitalism]]” and reductionism. Vitalism held essentially that some features of living organisms, including life itself, were not amenable to a physico-chemical explanation, and so asserted that high level constructs were essential to understanding and explanation.
||[[First Law]] (Principle of Conservation of Energy):&nbsp;Between any two equilibrium states, the change in internal energy is equal to the difference of the heat transfer into the system and work done by the system.
|-
||[[Second Law]] (Carnot's Principle):&nbsp;A natural process that starts in one equilibrium state and ends in another will go in a direction that causes the [[entropy (thermodynamics)|entropy]] of the system plus the environment to increase for an irreversible process and to remain constant for a reversible process.
|}
A '''scientific theory'''<ref>In science, the term "theory" indicates a logically connected set of hypotheses supported by a significant body of evidence. In daily life the term is used as in "that's just your theory", a hunch which may or may not be correct. This difference in meaning leads to miscommunication between scientists and laypersons, see: Helen Quinn, ''[http://ptonline.aip.org/getpdf/servlet/GetPDFServlet?filetype=pdf&id=PHTOAD000060000001000008000001&idtype=cvips Belief and knowledge&mdash;a plea about language]'', Physics Today, January 2007. </ref> is an overarching world view in an area of science. A theory may include statements of general scientific laws, such as the [[Laws of Thermodynamics]], it has a logical structure and includes axioms and defined concepts, and broadly it seeks to provide a coherent explanation of a large body of observations, and to bind these together with a set of related hypotheses. Theories are a necessary part of science because they determine a common language by which scientists in a field can communicate &mdash; communication of ideas depends upon scientists sharing key assumptions and using a common terminology. A particular theory is adopted by a scientific community for complex reasons; theories are preferred when they are successful in explaining a wide body of observations, but also when they are elegant, aesthetically satisfying in a way that is hard to define. This is sometimes expressed as a preference for simple, clear explanations. In the 14th century, the English logician and Franciscan friar [[William of Ockham]] formulated the 'law of parsimony', commonly known as '[[Ockham's razor]]' &mdash; "entities should not be multiplied more than is needed" (in Latin, ''entia non sunt multiplicanda praeter necessitatem'').  


The reductionist approach has asigned a particular importance to precise measurement of observable quantities. Scientific measurements are usually tabulated, graphed, or mapped, and statistical analyses of them; often these representations of the data using tools and conventions that are at a given time, accepted and understood by scientists working within a given field. The measurements often require specialized instruments such as thermometers, microscopes, or voltmeters, whose properties and limitations are familiar to others in the field, and the progress of a scientific field is usually intimately tied to their development. Measurements also demand the use of ''[[operational definition]]s''. A scientific quantity is defined precisely by how it is measured, in terms that enable other scientists to reproduce the measurements. In many cases, this ultimately involves internationally agreed ‘standards’. For example, [[electrical current]], measured in amperes, can be defined in terms of the mass of silver deposited in a certain time on an electrode in an electrochemical device that is described in some detail. The scientific definition of a term sometimes differs substantially from their [[natural language]] usage. For example, [[mass]] and [[weight]] overlap in meaning in common use, but have different meanings in physics. Scientific quantities are often characterized by their [[units of measure]] which can later be described in terms of conventional [[physical unit]]s when communicating the work. Measurements are not reports of absolute truth, all measurements are accompanied by the possibility of error in measurement, so they are usually accompanied by estimates of their [[uncertainty]], This is often estimated by making repeated measurements, and seeing by how much these differ. Counts of things, such as the number of people in a nation at a particular time, may also have an uncertainty due to limitations of the method used. Counts may only represent a sample of desired quantities, with an uncertainty that depends upon the sampling method used and the number of samples taken.
An example of a current theory is the Theory of [[Evolution]] by [[natural selection|Natural Selection]]. This seeks to explain the characteristics of all currently living organisms as the products of evolution, acting mainly by natural selection of organisms for reproductive success. The foundation of this theory is that, within any single species, individuals differ in the exact composition of their genes. These differences arise because of spontaneous random mutations in the genes, and because, in sexually reproducing organisms, every organism will inherit a different combination of genes from their parents, and because, independently of sexuality, there are mechanisms for generating novel genes by rearrangement of existing genes, and mechanisms for changing the way a gene functions. These processes for generating inheritable novelty produce differences in the traits of the individual organisms which can mean that some individuals are more likely to survive and reproduce than others, so the particular genes that they carry are more likely to be propagated in the next generation. Over time, beneficial genes &mdash; those that confer advantages to the individuals that carry them &mdash; will accumulate in a population, and maladaptive genes will be eliminated. Accordingly, over many generations, the characteristics of a population will change &mdash; the population will evolve. Eventually, in some circumstances, such as when a population is geographically isolated and subject to different environmental challenges, this can give rise to a new species.
 
It is not in the scope of this article to explain this theory fully or to defend it, but here we simply note a few features of this theory that are common to all theories. First, the theory explains a very large body of knowledge &mdash; the origin of the characteristics of all living things. Second, the theory involves presumptions: in this case, one presumption is that no intelligent creator directs the process of evolution. The theory cannot contradict the thesis that there is such an intelligent creator, it only declares that it is not necessary to invoke the existence of an intelligent creator to explain evolution. The theory does give an explanation for how living systems emerged from the non-living world. Third, the theory gives rise to hypotheses and to predictions. One hypothesis is that all life arises from common ancestors, and a prediction from this is that the genes of different species will show evidence for this, in that the genes that characterise different species will differ by a degree that is related to the time when the fossil record tells us that the species diverged. Fourth, the theory has undergone continual development and embellishment since it was first articulated by Charles Darwin, indeed the theory was proposed when virtually nothing was known of genes.
 
The Theory of [[natural selection]] is generally regarded as one of the 'cornerstones' of modern biology, but in a strict sense it is difficult to see it as falsifiable. It is accepted less because of the weight of experimental evidence, or because of its success in withstanding attempted disproof, but because of aesthetic considerations. In its essence it is seductively simple, and the force of its logic makes it seem self evidently true to contemporary biologists; it has a sweeping power to explain many diverse things, and it has succeeded, despite its simplicity, in stimulating many important ideas about the mechanisms underlying genes, their functions and their mechanisms of inheritance.
 
To say that the Theory is generally accepted is not to say that biologists are fully in agreement with each other; they are not, there is considerable debate and disagreement about many aspects of the Theory, especially about which of the many mechanisms of natural selection are most important. There are also alternatives, notably the Theory of [[Intelligent Design]]. This theory is based on the conclusion of its proponents that natural selection alone is incapable of explaining the evolution of highly complex organisms, and it postulates that some intelligence must have been involved in their design. The theory of Intelligent Design is accepted by very few biologists; most do not agree that the theory of natural selection cannot account for the complexity of living creatures, and so regard the concept of an intelligent designer as in breach of Ockham's razor.  
 
For Popper, no theory can ever be shown to be true - a theory may be corroborated by evidence, but can never be verified. He regarded the old scientific ideal of certain, demonstrable knowledge as illusory: that we can be certain about our faith, but scientific statements are forever in doubt. It is not possession of knowledge that makes the "man of science", but the "persistent and reckless ''quest'' for truth." In his words:
<blockquote>''Science does not rest upon solid bedrock. The bold structure of its theories rises, as it were, above a swamp. It is like a building erected on piles...if we stop driving the piles deeper, it is not because we have reached firm ground. We simply stop when we are satisfied that the piles are firm enough to carry the structure, at least for the time being.'' (Popper, K (1959) ''The Logic of Scientific Discovery'')</blockquote>


==The scientific method in practice==
==The scientific method in practice==
The UK Research Charity [[Cancer UK]] gave an outline of the scientific method, as practised by their scientists [http://info.cancerresearchuk.org/cancerandresearch/aboutcancerresearch/thescientificmethod/]. The quotes that follow are all from this outline
While scientists disagree among themselves and between themselves about whether there is a general "scientific method" and if so exactly what it involves, in any given field there are always some practices that are accepted as scientific good practice and others that are not. When scientists give expert evidence in Courts of Law, their evidence is given particular weight, reflecting the respect that is given to good scientific practice. In 1993, in the [[Daubert v. Merrell Dow Pharmaceuticals]] decision, the U.S. Supreme Court accorded a special status to 'The Scientific Method', in ruling that "… to qualify as 'scientific knowledge' an inference or assertion must be derived by the scientific method. Proposed testimony must be supported by appropriate validation - i.e., 'good grounds', based on what is known." The Court also stated that "A new theory or explanation must generally survive a period of testing, review, and refinement before achieving scientific acceptance. This process does not merely reflect the scientific method, it is the scientific method."<ref> [http://straylight.law.cornell.edu/supct/html/92-102.ZS.html Text of the opinion, LII, Cornell University]; [http://www.defendingscience.org/upload/Daubert-The-Most-Influential-Supreme-Court-Decision-You-ve-Never-Heard-Of-2003.pdf Daubert-The Most Influential Supreme Court Decision You've Never Heard of]</ref>
<blockquote> ''[Scientists] start by making an educated guess about what they think the answer might be, based on all the available evidence they have. This is known as forming an hypothesis. They then try to prove if their hypothesis is right or wrong.''
 
   
The UK Research Charity ''Cancer Research UK'' gives an outline of the scientific method, as practised by their scientists<ref name=CR-UK>[http://info.cancerresearchuk.org/cancerandresearch/aboutcancerresearch/thescientificmethod/ Science fact or fiction?], from Cancer Research UK</ref>.  
''Researchers carry out carefully designed studies, often known as experiments, to test their hypothesis. They collect and record detailed information from the studies. They look carefully at the results to work out if their hypothesis is right or wrong…'' </blockquote>
 
Once predictions are made, they can be ''tested'' by experiments. If the outcome contradicts the predictions, then explanations may be sought before the hypothesis is discarded as false. Sometimes there is a flaw in the experimental design, only recognised in retrospect. If the results confirm the predictions, then the hypotheses might still be wrong and if important, will be subjected to further testing. Scientists keep detailed records, both to provide evidence of the effectiveness and integrity of the procedure and to ensure that the experiments can be reproduced reliably. This tradition can be seen in the work of [[Hipparchus (astronomer)|Hipparchus (190 BCE - 120 BCE)]], when determining a value for the precession of the Earth over 2100 years ago, and 1000 years before Al-Batani.
===Hypotheses===
{|align="right" cellpadding="10" style="background:lightgray; width:30%; border: 1px solid #aaa; margin:20px; font-size: 93%; font-family: Gill Sans MT;"
 
|It is always safe and philosophic to distinguish, as much as is in our power, fact from theory; the experience of past ages is sufficient to show us the wisdom of such a course; and considering the constant tendency of the mind to rest on an assumption, and, when it answers every present purpose, to forget that it is an assumption, we ought to remember that it, in such cases, becomes a prejudice, and inevitably interferes, more or less, with a clear-sighted judgment. I cannot doubt but that he who, as a wise philosopher, has most power of penetrating the secrets of nature, and guessing by hypothesis at her mode of working, will also be most careful, for his own safe progress and that of others, to distinguish that knowledge which consists of assumption, by which I mean theory and hypothesis, from that which is the knowledge of facts and laws; never raising the former to the dignity or authority of the latter, nor confusing the latter more than is inevitable with the former.
 
:::&mdash;Michael Faraday<ref name=fara1844v2>Faraday M. (1844) ''Experimental Researches in Electricity''.  Volume 2. Richard and John Edward Taylor, printers and publishers to the University of London. | [http://books.google.com/books?id=2oSFAAAAIAAJ&printsec=frontcover#v=onepage&q&f=false Google Book full-text].
*"It is always safe and philosophic to distinguish...", pp. 285-286.</ref>
 
|}
<blockquote> ''[Scientists] start by making an educated guess about what they think the answer might be, based on all the available evidence they have. This is known as forming an hypothesis.''<ref>This quote and the ones that follow are from the ''Cancer Research UK'' outline.</ref></blockquote>
 
A ''hypothesis'' is a proposed explanation of a phenomenon. It may be an “inspired guess”, a “bold speculation”, embedded in current understanding yet going beyond that to assert something that we do not know for sure as a way of explaining something not otherwise accounted for. Most importantly, a scientific hypothesis is something that has ''consequences'', it leads to predictions and these can be tested by experiments. If the predictions prove wrong, the hypothesis is discarded, otherwise it is put to further test. If it resists determined attempts to disprove it, then it might come to be accepted, at least for the moment, as 'true'.
 
Scientists use many different means to generate hypotheses, including their own creative imagination, ideas from other fields, and by [[induction (philosophy)|induction]]. [[Charles Sanders Peirce]] (1839-1914) described the incipient stages of [[inquiry]], instigated by the "irritation of doubt" to venture a plausible guess, as ''[[Inquiry#Abduction|abductive reasoning]]'' <ref>[http://plato.stanford.edu/entries/peirce/ Charles Sanders Peirce] entry at the Stanford Encyclopedia of Philosophy</ref>. The history of science is full of stories of scientists claiming a "flash of inspiration" which motivated them. One of the best known is from the chemist [[August Kekulé]] (1829-1896), who proposed that structure of molecules followed particular rules. Kekulé recounted that the structure of benzene came to him in a dream, in which rows of atoms wound like serpents before him; one of the serpents seized its own tail: "the form whirled mockingly before my eyes. I came awake like a flash of lightning. This time also I spent the remainder of the night working out the consequences of the hypothesis".<ref>cited in Bargar RR, Duncan JK (1982) Cultivating creative endeavor in doctoral research ''J Higher Educ 53:1-31 [http://dx.doi.org/doi:10.2307/1981536  doi]</ref>
 
===Experiments and observations===
<blockquote>''Researchers carry out carefully designed studies, often known as experiments, to test their hypothesis. They collect and record detailed information from the studies. They look carefully at the results to work out if their hypothesis is right or wrong…'' </blockquote>
An ''experiment'' is a procedure carried out under controlled conditions to gain new information or better understanding. Not all science involves experimentation; for example the human genome project largely involves (highly technical) interpretation of gene sequences, but the data were obtained by experimental investigation. Equally, not all experiments are designed to test hypotheses; some extend our knowledge by making more detailed observations of known phenomena, or by exploring new or unexplained phenomena more fully.
 
Between 1907 and 1917, the theoretical physicist [[Albert Einstein]] (1879-1955) developed the [[General theory of relativity]], which, amongst other things, explains gravitation as a manifestation of curvature of space and time. Several predictions can be derived from Einstein's theory of [[General Relativity]], and one prediction was that light will appear to 'bend' in a gravitational field by an amount that depends on the strength of the field. [[Arthur Eddington]] (1882-1994) devised experiments to test this prediction; his observations, made during a solar eclipse in 1919, supported General Relativity and showed the restrictions in applicability of the  accepted theory of gravitation, credited to [[Isaac Newton]] (1643-1727).
 
[[Werner Heisenberg]] (1901-1976) was one of the physicists responsible for developing the theory of [[quantum mechanics]] (which so far resisted logical unification with general relativity). In a quote that he attributed to Albert Einstein, he stressed how observations depend upon the theories that are held at the time they are made <ref>[[Werner Heisenberg|Heisenberg, Werner]] (1971) ''Physics and Beyond, Encounters and Conversations'', A.J. Pomerans (trans.), Harper and Row, New York, NY  pp.63–64</ref> "The phenomenon under observation produces certain events in our measuring apparatus. As a result, further processes take place in the apparatus, which eventually and by complicated paths produce sense impressions and help us to fix the effects in our consciousness. Along this whole path—from the phenomenon to its fixation in our consciousness—we must be able to tell how nature functions, must know the natural laws at least in practical terms, before we can claim to have observed anything at all. Only theory, that is, knowledge of natural laws, enables us to deduce the underlying phenomena from our sense impressions."
 
For Karl Popper, theory was profoundly important in science; a theory encompasses the preconceptions by which the world is viewed, and defines what we choose to study, and how we study it and understand it. He recognised that theories are not discarded lightly, and a theory might be retained long after it has been shown to be inconsistent with known facts ([[anomalies]]). However, the recognition of anomalies drives scientists to adjust the theory, and if the anomalies continue to accumulate, will drive them to develop alternative theories. Popper proposed that a theory should be judged by the extent to which it inspires testable hypotheses. While theories always contain many elements that are not falsifiable, Popper argued that these should be as few as possible. However, scientists also seek theories that are "elegant"; a theory should yield clear, simple explanations of complex phenomena, that are intellectually satisfying in being logically coherent, rich in content, and involving no miracles or other supernatural devices.
 
===Peer review===
===Peer review===
<blockquote> ''…Once they have completed their study, the researchers write up their results and conclusions. And they try to publish them as a paper in a scientific journal. Before the work can be published, it must be checked by a number of independent researchers who are experts in a relevant field. This process is called ‘peer review’, and involves scrutinising the research to see if there are any flaws that invalidate the results…'' </blockquote>
<blockquote> ''…Once they have completed their study, the researchers write up their results and conclusions. And they try to publish them as a paper in a scientific journal. Before the work can be published, it must be checked by a number of independent researchers who are experts in a relevant field. This process is called ‘peer review’, and involves scrutinising the research to see if there are any flaws that invalidate the results…'' </blockquote>
Manuscripts submitted for publication in scientific journals are normally sent by the editor to (usually one to three) fellow (usually anonymous) scientists who are familiar with the field for evaluation. The referees may or may not recommend publication, publication with suggested modifications, or, sometimes, publication in another journal. This helps to keep the scientific literature free of unscientific work, reduces obvious errors, and generally improves the quality of the scientific literature. The peer review process has been criticised, but is very widely adopted by the scientific community. Nevertheless, there are inevtable weaknesses; first it is very much easier to publish data that are consistent with generally accepted theory than to publish data that contradict accepted theory: the 'bar' for acceptance of work is higher the more remarkable the claim. This helps to ensure the stability of the body of accepted theory, but also means that the appearance of the extent to which a conventionally accepted theory is supported by evidence might be misleading - boosted by poor quality supportive work and protected against higher quality opposing work.  
The main way of disseminating scientific information is through the peer-reviewed scientific literature. This is a vast array of academic journals that was once mainly restricted to the libraries of Universities and research institutes, but these are now mostly available on-line through the internet, and often they are freely available. There are many thousands of these journals, some of which are managed and owned by scientific societies, others by commercial publishers. The better scientific journals publish just a small proportion of the manuscripts submitted to them, and only after a process of peer review and revision. An article published in the peer-reviewed literature that describes the outcome of a series of experiments is known as a 'scientific paper'. Over their careers, many scientists may publish more than a hundred such papers, but even for the most successful scientists very few of their papers have a major, lasting influence. Some scientists have achieved wide acclaim despite publishing very few papers, because of the exceptional importance of those few. One measure of the influence of a paper is how often it is 'cited' &mdash; referenced in other scientific papers. As most scientific papers include references to about 30 other papers, an average paper will eventually accrue about 30 'citations'. [[Frederick Sanger]], twice winner of the [[Nobel Prize for Chemistry]] (1958 and 1980)<ref>[http://nobelprize.org/nobel_prizes/chemistry/laureates/1958/ 1958 Nobel Prize for Chemistry] and [http://nobelprize.org/nobel_prizes/chemistry/laureates/1980/ 1980 Nobel Prize for Chemistry])</ref> published about 70 papers in his whole career; 30 of these have been cited more than 100 times each, and four of them more than 1000 times each.


On the other hand, originality, importance and interest are particularly important in 'high impact' general journals of science -see for example the [http://www.nature.com/nature/submit/get_published/index.html author guidelines] for ''[[Nature (journal)|Nature]]'', thus if controversial work appears to be very convincing then it stands a good chance of being published in such journals
Manuscripts submitted for publication in scientific journals are normally sent by the editor to (usually one to three) other scientists for evaluation. These 'expert referees' advise the editor about the suitability of the paper for publication in the journal. They also report, usually anonymously, on its strengths and weaknesses, pointing out any errors or omissions that they noticed and offering suggestions for how the paper might be improved by revision or by further experiments. With this advice, the editor might reject the paper or decide that it might be acceptable if appropriately revised.  
Criticisms (see [[Critical theory]]) of journal publication priorities are that they are so vaguely defined, highly subjective and open to ideological, or even political, manipulation, that they can sem to impede rather than promote scientific discovery. Apparent censorship by refusing to publish ideas unpopular with mainstream scientists has soured the popular perception of scientists, by apparently contradicting their claim to be objective seekers of truth.


==The scientific literature==
Peer review has been widely adopted by the scientific community, but has weaknesses. It is easier to publish data that are consistent with a generally accepted theory than data that contradict it. This helps to ensure the stability of the accepted theory, but also means that the appearance of the extent to which a current theory is supported by evidence might be misleading &mdash; boosted by a poorly scrutinised supportive work while insulated from criticism. The biologist Lynn Margulis encountered great difficulty in publishing her theory that the eukaryotic cell is a symbiotic union of primitive prokaryotic cells. In 1966, she wrote a theoretical paper entitled ''The Origin of Mitosing Cells''; it was "rejected by about fifteen scientific journals," as Margulis recalled. Finally accepted by ''The Journal of Theoretical Biology'', it is now considered a landmark in modern [[endosymbiotic theory]].<ref>Sagan L (1967) On the origin of mitosing cells" ''J. Theor Biol'' '''14''':255-74 [http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=PubMed&list_uids=11541392&dopt=Citation Abstract]</ref> In 1995, [[Richard Dawkins]] said, "I greatly admire Lynn Margulis's sheer courage and stamina in sticking by the endosymbiosis theory, and carrying it through from being an unorthodoxy to an orthodoxy." <ref>John Brockman, [http://www.edge.org/documents/ThirdCulture/n-Ch.7.html ''The Third Culture''], New York: Touchstone 1995, 144</ref>
 
To the defense of the possible  conservatism of reviewers, it must be remarked that they must trust at face value the experimental data that are in the manuscript before them. They cannot repeat the experiments and verify their outcome&mdash;they lack the time and often the possibility. All a reviewer can do is  decide whether experimental data  look "reasonable", which implies a judgment about the plausibility of the data  in the light of the ruling paradigm.  There are some famous cases of fraud that took years before unveiling, mainly because the fraud took care that his/her faked results looked "reasonable". Conversely, experimental data and theories that look "unreasonable" (in contradiction with the dominant paradigm) may need a long time (and affirmation by different laboratories) before they are deemed publishable. Notorious is the affair around the publication of  Benveniste's  "unreasonable"  experimental data on the [[memory of water]] in [[Nature]].
 
===The scientific literature===
<blockquote> ''…If the study is found to be good enough, the findings are published and acknowledged by the wider scientific community…'' </blockquote>
<blockquote> ''…If the study is found to be good enough, the findings are published and acknowledged by the wider scientific community…'' </blockquote>
However [[Thomas Kuhn]] argued that scientists are


Sir [[Peter Medawar]], Nobel laureate in Physiology and Medicine in his article [http://maagar.openu.ac.il/opus/static/binaries/editor/bank66/medawar_paper_fraud_1.pdf  “Is the scientific paper a fraud?”] answered yes, "The scientific paper in its orthodox form does embody a totally mistaken conception, even a travesty, of the nature of scientific thought." In scientific papers, the results of an experiment are interpreted only at the end, in the discussion section, giving the impression that those conclusions are drawn by induction or deduction from the reported evidence. Instead, explains Medawar, the expectations that a scientist begins with provide the incentive for the experiments, and determine their nature, and they determine which observations are relevant and which are not. Only in the light of these initial expectations that the activities described in a paper have any meaning at all. The expectation, the original hypothesis, according to Medawar, is not the product of inductive reasoning but of inspiration, educated guesswork. Medawar was echoing Karl Popper, who proclaimed that
The way in which scientific research is presented in published form is governed by sometimes quite rigid conventions. Although they differ slightly from one field to another, a scientific paper generally has an 'Introduction', which gives a brief background to the question that is being addressed, a 'Methods' section, which details the experimental procedures in enough detail to allow them to be replicated independently, a 'Results' section which objectively details the findings, and a 'Discussion' section in which the authors interpret the findings and relate them to other work.  


==Confirmation==
[[Peter Medawar]] (1915-1987), Nobel laureate in Physiology and Medicine, in his article “Is the scientific paper a fraud?” <ref>Medawar, P. B. [http://maagar.openu.ac.il/opus/static/binaries/editor/bank66/medawar_paper_fraud_1.pdf  “Is the scientific paper a fraud?”], BBC Third Programme, Listener 70, 12 September 1963. </ref> argued that the scientific paper in its orthodox form embodies "a totally mistaken conception, even a travesty, of the nature of scientific thought." Because the results of an experiment are interpreted only at the end (in the discussion section) of scientific papers, this gives the impression that those conclusions are drawn by induction or deduction from the reported evidence. However, explains Medawar, it is the ''expectations'' that a scientist begins with that provide the incentive for the experiments, determine their nature, and determine which observations are relevant and which are not. Only in the light of these initial expectations do the activities described in a paper have any meaning at all. The expectation, the original hypothesis, according to Medawar, is not the product of inductive reasoning but of inspiration &mdash; educated guesswork.
 
===Confirmation===
<blockquote> ''…But, it isn’t enough to prove a hypothesis once. Other researchers must also be able to repeat the study and produce the same results, if the hypothesis is to remain valid…'' </blockquote>
<blockquote> ''…But, it isn’t enough to prove a hypothesis once. Other researchers must also be able to repeat the study and produce the same results, if the hypothesis is to remain valid…'' </blockquote>
Sometimes experimenters make systematic errors during their experiments, Consequently, it is a common practice for other scientists to attempt to repeat experiments, especially experiments that have yielded unexpected results<ref> [[Georg Wilhelm Richmann]] was killed by [[lightning]] ([[1753]]) when attempting to replicate the [[1752]] [[kite flying|kite]] [[experiment]] of [[Benjamin Franklin]]. See, e.g., Physics Today, Vol. 59, #1, p42. [http://www.physicstoday.org/vol-59/iss-1/p42.html]</ref>. Accordingly, scientists keep detailed records of their experiments, to provide evidence of their effectiveness and integrity and assist in reproduction. However, it is not possible for a scientist to record ''everything'' that took place in an experiment. He must select the facts that he believes are relevant to the experiment. This may lead to problems if some supposedly irrelevant feature is questioned. For example, [[Heinrich Hertz]] did not report the size of the room that he used to test Maxwell's equations, and this turned out to account for a deviation in the results. The problem is that parts of the theory must be assumed in order to select and report the experimental conditions. Observations are thus sometimes described as being 'theory-laden'.
Sometimes scientists make errors in the design, execution or analysis of their experiments, so it is common for other scientists to try to repeat experiments, especially when the results were surprising. <ref>Georg Wilhelm Richmann was killed by lightning in 1753 when attempting to replicate the kite experiment of Benjamin Franklin. Krider P (2006) Benjamin Franklin and lightning rods ''Physics Today'' 59:42, [http://ptonline.aip.org/journals/doc/PHTOAD-ft/vol_59/iss_1/42_1.shtml available online]</ref> Accordingly, scientists keep detailed records of their experiments, to provide evidence of their effectiveness and integrity and assist in reproduction. Generally, in publishing their work, it is considered essential that scientists describe their methods in enough detail to allow them to be repeated by others. However, a scientist cannot record ''everything'' about an experiment; he (or she) reports what he believes to be relevant. This can cause problems if some supposedly irrelevant feature is questioned. For example, Sidney Ringer's experiments with isolated frog hearts first led him to declare that the heart could continue to beat if kept in a simple saline solution. However, he later discovered that the solution had been made up not with distilled water but with London tap water, which contained a significant amount of calcium carbonate. He retracted his first reports, and is now known as the scientist who showed that calcium is important for the contractions of the heart. <ref>Carafoli E (2002) Calcium signalling: a tale for all seasons ''PNAS USA'' [http://www.pnas.org/cgi/content/abstract/99/3/1115 99:115-22]</ref>
 
===Statistics===
<blockquote>''…If the initial study was carried out using a small number of samples or people, larger studies are also needed. This is to make sure the hypothesis remains valid for bigger group and isn't due to chance variation…'' </blockquote>
 
Scientists analyse their data using the theory and methods of [[Statistics]], which arose from [[probability theory]]. Statistical analysis essentially involves methods for drawing conclusions from data that involve multiple sources of error.
 
Statistical analysis is a part of hypothesis testing in many areas of science. This formalises the criteria for disproof by allowing statements of the form:
"If our hypothesis is true, the chance of getting the results that we observed is (say) only 1 in 20 or less (P < 0.05); therefore the hypothesis is probably wrong, and so we reject it.''
For instance, we might predict that a given chemical will produce a certain effect. However what we often test is not this, but the ''[[null hypothesis]]'' - that the chemical will have '''no''' effect. The reason is that, if our original hypothesis is vague about how big an effect to expect, then we cannot disprove it, as we can't exclude the possibility that the effect is too small to measure. However, we ''can'' disprove the null hypothesis (by showing an effect). Ideally, we choose hypotheses that give precise predictions, but this is often unrealistic. In medicine for example, we might expect a new drug to be effective in a particular condition from our understanding of its mechanism of action. Even so, we might not know how big an effect to expect because of many uncertainties - how many people will be resistant to the drug? for example, and how quickly will tolerance to the drug develop in people who respond well?


It seems to be only very rarely that scientists falsify their results; any scientist who does so takes an enormous risk, because if the claim is important it is likely to be subjected to very detailed scrutiny, and the reputation of a scientist depends upon the credibility of his or her work. Nevertheless there have been many well publicised examples of scientific fraud, and some have blamed the insecurity of employment of scientists and the extreme pressure to win grant funding for these instances. Under Federal regulations <ref>the Federal Register, vol 65, no. 235, December 6, 2000</ref>"A finding of research misconduct requires that:
This is not hypothesis testing in Popper's sense, because the hypothesis is not put at any hazard of disproof. Verification of this type is something that Popper considered to be, at best, weak corroborative evidence, partly because it is impossible to measure the support that such evidence provides. <ref>In appendix ix to ''The Logic'', Popper states: "As to degree of corroboration, it is nothing but a measure of the degree to which hypothesis ''h'' has been tested...it must not be interpreted therefore as a degree of the rationality of our belief in the truth of ''h''...rather it is a measure of the rationality of accepting, tentatively, a problematic guess."</ref>
There be a significant departure from accepted practices of the relevant research community; and
The misconduct be committed intentionally, or knowingly, or recklessly; and
The allegation be proven by a preponderance of evidence."


Honor in Science, published by  Sigma Xi , quotes [[C.P. Snow]] (The Search, 1959): "The only ethical principle which has made science possible is that the truth shall be told all the time. If we do not penalise false statements made in error, we open up the way, don’t you see, for false statements by intention. And of course a false statement of fact, made deliberately, is the most serious crime a scientist can commit."
In the 18th century, an English clergyman, [[Thomas Bayes]] (1702-1761) proved a result, now known as [[Bayes Theorem]], that, in some interpretations, provides a formal method for revising beliefs in the light of new evidence <ref>Bellhouse DR (2004) [http://www.york.ac.uk/depts/maths/histstat/bayesbiog.pdf The reverend Thomas Bayes FRS: a biography to celebrate the tercentenary of his birth] Statistical Science 19:3-43</ref>. It has been argued that [[Bayesian statistics]] can be used to provide a basis for support by induction, and some areas of science use these approaches. Bayesian statistics measures how the probability that a hypothesis is true changes as a result of observations, but it depends on assigning initial values to the probabilities of alternative outcomes of an experiment. This is not always possible because of the difficulty of assigning these ''a priori'' probabilities in any meaningful way.
It goes on to say:
"It is not sufficient for the scientist to admit that all human activity, including research, is liable to involve errors; he or she has a moral obligation to minimize the possibility of error by checking and rechecking the validity of the data and the conclusions that are drawn from the data."


==Statistics==
===Progress and controversy in science===
<blockquote>''…If the initial study was carried out using a small number of samples or people, larger studies are also needed. This is to make sure the hypothesis remains valid for bigger group and isn't due to chance variation…'' </blockquote>
<blockquote> ''...Over time, scientific opinion can change. This is because new technologies can allow us to re-examine old questions in greater detail.'' </blockquote>
There is an important school of Bayesian statistics that seeks to provide a statistical basis for support by induction, and some areas of science use these approaches; but in much of science this approach is not tenable because of the difficulty of attaching a priori probabilities in any meaningful way to the alternative predicted outcomes of an experiment. Popper was a mathematical logician, and argued strongly against Bayesian approaches. Popper was interested in how "support" for a theory could be measures by quantifying the degree of corroborative support, he did not dismiss statistical approaches lightly and explored their utility in detail. But in appendix ix to The Logic he states: "As to degree of corroboration, it is nothing but a measure of the degree to which hypothesis h has been tested...it must not be interpreted therefore as a degree of the rationality of our belief in the truth of h...rather it is a measure of the rationality of accepting, tentatively, a problematic guess"
Although skepticism, or doubt, has long been recognised as an important element in all science, Kuhn argued that scientific opinion does not change easily in fundamental things. In particular, one theory or world view is replaced by another not because many scientists  are 'converted' to the new world view. Instead, a new theory begins as an unfashionable alternative that is often derided, but gains adherents as its advantages become apparent to new scientists entering the field, while the adherents of the old view fight a 'rear-guard action' to defend it. [[Barbara McClintock]]'s work on regulatory elements that control gene expression won her the Nobel Prize in Physiology or Medicine in 1983, but in 1953 she decided to stop trying to publish detailed accounts of her work, because of the puzzlement and hostility of her peers. In 1973 she wrote:
:"Over the years I have found that it is difficult if not impossible to bring to consciousness of another person the nature of his tacit assumptions when, by some special experiences, I have been made aware of them. ...One must await the right time for conceptual change"<ref>McClintock B (1987) The discovery and characterization of transposable elements: the collected papers of Barbara McClintock, ed John A. Moore. Garland Publishing, Inc. ISBN 0-8240-1391-3. (Introduction)</ref>


==Progress in science==
Kuhn focused attention on the unexplainable phenomena as the key to scientific revolutions, which he called "paradigm shifts". One example reported in ''The Structure of Scientific Revolutions'' dates back to the mathematical astronomer Claudius [[Ptolemy]], who lived in Egypt in the 2nd century CE. The improvements in astronomical observation, and the accumulation of more data during that time required more and more elaborate explanations to reconcile the observational data with the accepted belief that the earth was the centre of the solar system, and indeed of the universe. By the time of [[Copernicus]] (1473-1543), so much evidence had accumulated suggesting that the sun was in fact the center of the solar system, the whole infrastructure of theories broke down, leading the way to acceptance of a new heliocentric world picture. Yet, it took more than a century before all astronomers were convinced. When [[Einstein]] showed in 1905  that there is no [[ether (physics)|ether]], or at least that the concept is superfluous and may be removed from physics by Ockham's razor, many of the older generation of physicists did not accept this paradigm shift and died believing in ether; they were not converted, the ether concept died out.
<blockquote> ''…Over time, scientific opinion can change. This is because new technologies can allow us to re-examine old questions in greater detail.'' </blockquote>


New observations about natural phenomena continue to lead to such revolutions in biology, plate tectonics, particle physics, and many other branches of science.


[[Image:Gravitational lens-full.jpg|right|thumb|200px|[[gravitational lensing|Einstein's prediction (1907): Light bends in a gravitational field]]]]
==Alternative views==
Einstein's theory of [[General Relativity]] makes several specific predictions about the observable structure of [[space-time]], such as a prediction that [[light]] bends in a [[gravitational field]] and that the amount of bending depends in a precise way on the strength of that gravitational field. [[Arthur Eddington]]'s observations made during a [[1919]] [[solar eclipse]] supported General Relativity rather than Newtonian [[gravitation]].
<blockquote>''"The progress of science is often affected more by the frailties of humans and their institutions than by the limitations of scientific measuring devices. The scientific method is only as effective as the humans using it. It does not automatically lead to progress."'' Steven S. Zumdahl</blockquote>
The success of science, as measured by the technological achievements that have changed our world, have led many to conclude that this success is because of the methodological rules that scientists follow. However, not all philosophers accept this conclusion; for example, [[Paul Feyerabend]] (1924-1994) denied that science is genuinely a methodological process. In his book ''Against Method'' he argued that scientific progress is ''not'' the result of applying any particular rules.<ref> Feyerabend PK (1975) [http://www.marxists.org/reference/subject/philosophy/works/ge/feyerabe.htm ''Against Method, Outline of an Anarchistic Theory of Knowledge''] Reprinted, Verso, London, UK, 1978; for a critical review, see  [http://www.springerlink.com/content/p704x52113gg17j7/fulltext.pdf "Against too much method"] by John Worrall</ref> Instead, he concluded almost that 'anything goes', in that for any particular 'rule' there are abundant examples of successful science that have proceeded in a way that seems to contradict it.<ref>[http://www.galilean-library.org/feyerabend.html Feyerabend's 'anything goes' argument explained] at the Galilean Library. Criticisms such as his led to the [[strong programme]], a radical approach to the sociology of science.
</ref> To Feyeraband, there is no real difference between science and other areas of human activity characterised by reasoned thought. A similar sentiment was expressed by [[T.H. Huxley]] in  1863: "The method of scientific investigation is nothing but the expression of the necessary mode or working of the human mind. It is simply the mode at which all phenomena are reasoned about, rendered precise and exact."<ref>Huxley TH (1863) [http://www.fordham.edu/halsall/mod/1863huxley.html From a 1863 lecture series aimed at making science understandable to non-specialists]</ref>


==See Also==
Some scientists focus their activity on making precise and detailed observations of a phenomenon, gathering data, organizing it in sensible ways, making it accessible to other scientists. We do not disqualify those scientists as ‘scientists’ on the grounds they do not employ a scientific method. Other scientists might use their observational data to generate testable hypotheses, and other scientists might test those hypotheses by experiment, and others try to reproduce the findings. That illustrates an instance of the scientific method in action realized by the combined effort of two or more scientists working with different methods, not necessarily in one generation. Regardless of the hopefully rational approach that each scientist employs in her 'scientific method', none can leave their biases and passions outside their mind. Sometimes biases and passions contribute the advancement of science. The scientific method is the endeavor of humans, prone to error for many reasons, prone to creative insights by nature. But scientists agree on the need for verifiable knowledge, and they cannot suppress the emergence of new perspectives and paradigms. 
[[Models of scientific inquiry]]
[[Pseudoscience]]


In his 1958 book, ''Personal Knowledge,'' the chemist and philosopher [[Michael Polanyi]] (1891-1976) criticized the view that the scientific method is purely objective and generates objective knowledge. Polanyi thought that this was a misunderstanding of the scientific method, and argued that scientists do and must follow their passions in appraising facts and in choosing which questions to investigate. He concluded that a structure of liberty is essential for the advancement of science &mdash; that the freedom to pursue science for its own sake is a prerequisite for the production of knowledge.<ref> [http://plato.stanford.edu/entries/relativism/ Relativism] entry at the Stanford Encyclopedia of Philosophy</ref>


==Notes and references==
==The changing nature of science==
<references/>
Charles Darwin was an amateur scientist, a man of independent means and broad ranging interests who worked to satisfy his own curiosity. Still in the early 20th century, science was the province of individuals with wide interests. Albert Einstein was working as clerk in a patent office in Bern in 1905, the year that he published four papers in ''Annalen der Physik'' that are now each recognised as hugely important; the four papers discuss the particulate nature of light; Brownian motion; the theory of special relativity; and the equivalence of matter and energy.
In the 20th century, science became largely professionalised, conducted increasingly by specialised experts employed in Universities or research institutes, and increasingly governed by the priorities of funding bodies, which in turn have become increasingly influenced by the political priorities of the Governments that are the source of the funding for research.


The 'lone scientist' is now a rare animal; most science is now a collaborative enterprise, often conducted in large teams where each member of the team supplies a specific area of specialised expertise. Most of Frederick Sanger's scientific papers, published between 1945 and 1980, were either authored by him alone or with just one other co-author. This is now unusual in the Life Sciences, where most papers have several authors and many have ten or more. In experimental high-energy physics, papers with more than 100 authors from 40 or more institutions are the rule.<ref>For example, see a randomly picked article in the May 2009 issue of the European Physical Journal C [http://dx.doi.org/10.1140/epjc/s10052-009-0995-1 DOI]</ref>


==Further reading==
Increasingly, scientists work towards specified ambitious goals; a prime example is the [[Human Genome Project]], a research program involving hundreds of laboratories across many countries directed at sequencing the entire human genome. This 13-year project, coordinated by the U.S. Department of Energy and the National Institutes of Health, was completed in 2003.
*The Keystones of Science project, sponsored by the journal ''[[Science (journal)|Science]]'' has selected a number of scientific articles from that journal and annotated them, illustrating how different parts embody the scientific method.  [http://www.sciencemag.org/feature/data/scope/keystone1/ Here] is an annotated example of the scientific method example.
* [[Francis Bacon (philosopher)|Bacon, Francis]] ''Novum Organum (The New Organon)'', 1620.  Bacon's work described many of the accepted principles, underscoring the importance of [[Theory]], empirical results, data gathering, experiment, and independent corroboration.
* [[John Dewey|Dewey, John]] (1991) ''How We Think'', D.C. Heath, Lexington, MA, 1910.  Reprinted, [[Prometheus Books]], Buffalo, NY
* [[Werner Heisenberg|Heisenberg, Werner]] (1971) ''Physics and Beyond, Encounters and Conversations'', A.J. Pomerans (trans.), Harper and Row, New York, NY  pp.63–64
* [[Bruno Latour|Latour, Bruno]], ''Science in Action, How to Follow Scientists and Engineers through Society'', Harvard University Press, Cambridge, MA, 1987.
* McComas WF, ed. [http://www.usc.edu/dept/education/science-edu/Myths%20of%20Science.pdf The Principle Elements of the Nature of Science: Dispelling the Myths], from ''The Nature of Science in Science Education'', pp53-70, Kluwer Academic Publishers, Netherlands 1998.
* [[Henri Poincaré|Poincaré H]] (1905) ''Science and Hypothesis'' [http://spartan.ac.brocku.ca/~lward/Poincare/Poincare_1905_toc.html Eprint]


==External links==
Thus the 20th century saw a transition from ''curiosity-driven research'' to ''hypothesis-driven research'' and then to ''goal-directed research''. These changes were accompanied by major changes in the sociology of the scientific community. Research scientists today mostly have a very narrowly specialised technical expertise, are professionally employed, funded directly or indirectly by Governments, research charities or industry, and generally work within a team that may be part of a multinational network of teams working to a common goal.
* [http://www.freeinquiry.com/intro-to-sci.html An Introduction to Science: Scientific Thinking and a scientific method] by Steven D. Schafersman.
* [http://teacher.nsrl.rochester.edu/phy_labs/AppendixE/AppendixE.html Introduction to a scientific method]
* [http://www.galilean-library.org/theory.html Theory-ladenness] by Paul Newall at The Galilean Library
* [http://pasadena.wr.usgs.gov/office/ganderson/es10/lectures/lecture01/lecture01.html Scientific Method]
* [http://www.swemorph.com/pdf/anaeng-r.pdf Analysis and Synthesis: On Scientific Method based on a study by Bernhard Riemann] From the [http://www.swemorph.com  Swedish Morphological Society]
* [http://www.sciencemadesimple.com/scientific_method.html Using the scientific method for designing science fair projects] from [http://www.sciencemadesimple.com Science Made Simple]


[[Category:Philosophy Workgroup]]
==Notes and references==
[[Category:CZ Live]]
{{reflist|2}}[[Category:Suggestion Bot Tag]]

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Statue of David Hume. "Man is a reasonable being; and as such, receives from science his proper food and nourishment: But so narrow are the bounds of human understanding, that little satisfaction can be hoped for in this particular..." Hume recognised clearly the difficulties in gaining a general understanding merely by accumulating observations.

Scientists use a scientific method to investigate phenomena and acquire knowledge. They base the method on verifiable observation — i.e., on replicable empirical evidence rather than on pure logic or supposition — and on the principles of reasoning.[1] [2] Scientists propose explanations — called hypotheses — for their observed phenomena, and perform experiments to determine whether the results accord with (support) the hypotheses or falsify them. They also formulate theories that encompass whole domains of inquiry, and which bind supported hypotheses together into logically coherent wholes. They refer to theories sometimes as ‘models’, which often have a mathematical or computational basis.[3] [4]


Components of the scientific method

Science is said to proceed on two legs, one of theory (or, loosely, of deduction) and the other of observation and experiment (or induction). Its progress, however, is less often a commanding stride than a kind of halting stagger — more like the path of the wandering minstrel than the straight-ruled trajectory of a military marching band. The development of science is influenced by intellectual fashions, is frequently dependent upon the growth of technology, and in any case, seldom can be planned far in advance, since its destination is usually unknown.
—Timothy Ferris, Coming of Age in the Milky Way (1988)[5]


(CC) Image: Cameron Neylon
A simplified depiction of the cyclic nature of scientific research: An initial observation triggers an idea that is being developed into a hypothesis which — if funds, equipment and the necessary expertise are available — may lead to experimental data (or other forms of verifiable evidence) that can support or contradict the hypothesis or other existing theoretical descriptions of the system at hand, which in turn can trigger independent replication or falsification of this particular experiment if the relevant information are made available to other researchers. Traditionally, this publication step would be achieved solely via articles in toll-access scientific journals but initiatives like Open access, Open Source and Open Data are increasingly making all these individual steps public, which is facilitated through the use of Web 2.0 technologies in what has come to be called Science 2.0.

Generally accepted components of a scientific method are:

  • Observation.[6] Observations do not just await discovery, rather they often result from active exploration, questioning, sharing ideas and information among scientists, thinking creatively. Moreover, according to most current views, observations do not come into view wholly independently of some predetermined or preconceived theory; scientists struggle to keep their preconceptions and presuppositions out of the picture.[7][8] Sometimes "believing is seeing".
  • Hypothesis. Hypotheses are general statements, formulated as plausible conjectures to explain existing observations and predict future observations.
  • Experiment.[9] An experiment is a procedure carried out under controlled conditions to discover an unknown effect; to provide confirming or disconforming evidence for a hypothesis, often based on whether a prediction of the hypothesis ensues; or, to illustrate an accepted theory. Not all areas of science involve direct experimentation; as an example for data-driven research, the Human Genome Project largely involved (highly technical) interpretation of gene sequences, but the data were obtained by experimental investigation.
  • Theory. A theory incorporates a set of supported hypotheses into a logical framework that overall explains the phenomenon studied. Not all of the statements of a theory are necessarily open to experimental testing, but many are expected to be for a theory to be considered scientific. The scientific method usually involves further testing of its accepted satisfactory overall explanation of a phenomenon, as natural phenomena usually have more observable features than the theorist knows at the time the theory hatches. A good theory will make accurate predictions about the behavioral aspects of the phenomenon studied, suggesting experiments to test its overall explanatory power.
  • Prediction. A prediction is a logical deduction from a hypothesis (or theory) by which the hypothesis (or theory) can be tested experimentally.
  • Testing. A 'test' of a hypothesis is an experiment, the results of which might falsify (disprove) the hypothesis; if the test does not falsify the hypothesis, the test is said to support ('confirm') the hypothesis. The same holds for testing theories.
  • Causal explanation. Satisfactory explanations are often regarded as those that establish a cause-effect relationship. However, many scientists argue that concepts of causality are not obligatory to science, but are well-defined only under particular conditions.[10] [11]
  • Skeptical open mindedness. Progress in extending existing theoretical frameworks is made possible by a scientific culture that encourages challenges to existing theory, while also demanding that far-reaching conjectures are validated by exceptional evidence.[12]

Philosophy of scientific methods

If the purpose of scientific methodology is to prescribe or expound a system of enquiry or even a code of practice for scientific behavior, then scientists seem to be able to get on very well without it. Most scientists receive no tuition in scientific method, but those who have been instructed perform no better as scientists than those who have not. Of what other branch of learning can it be said that it gives its proficients no advantage; that it need not be taught or, if taught, need not be learned? Peter Medawar[13]

Evolutionary processes and, in general, scientific explanations of the world are often in contrast with the immediate and simple explanations that our brain gives of reality (e.g. the sun seems to turn around the earth, the earth seems to be flat), and are influenced by what Francis Bacon called "idola"[[14]] (false notions or tendencies which distort the truth [[15]]).[16]

Non-scientists often represent science as a dry, mechanical activity, involving accumulating large numbers of facts, whether by simple observations or by technologically ingenious means. Indeed, this is an important part of science, and technological advances in our ability to interrogate the world have played an essential part in the advance of science: we need only consider how the light microscope, then the electron microscope, and now the scanning tunneling microscope[17] and two-photon laser scanning confocal microscopy have radically changed our understanding of the world. However, observations, things that we might sometimes call 'facts', are just the beginning. Thus, according to Charles Darwin (1809-1882), "science consists in grouping facts so that general laws or conclusions may be drawn from them."[18]

But what exactly do we mean by ‘facts’? We sometimes disagree about the ‘facts’ we see around us, and some things in the world are at odds with our understanding. How much can we trust our senses to allow us to believe what we see? How do scientists ‘group’ facts? How do they choose which facts to attend to, and is it possible to do this in an objective way? And having done this, how do they draw any broader conclusions? Most importantly, how can we ever know more than we observe directly? We live in a world that is not directly understandable: we all interpret everything that we see and hear and feel, and to make sense of what our senses tell us we need to construct explanations, or formulate theories. Our explanations identify some things as important and other things as irrelevant; they lead us to pay attention to some things and not others, and they lead us to expect some things to happen and not others — they lead, in other words, to predictions.

Nothing about this is unique to science, but scientists attempt to harness these universal elements of reasoning in a consistent, systematic and rigorous manner, and in a way that minimizes bias. What we call the 'scientific method' is an account of how scientists gather and report observations in ways that will be understood by other scientists and accepted as valid evidence, and how they construct explanations that are consistent with the world, and that can withstand logical and experimental scrutiny and provide the foundations for further increases in understanding.

For many, the scientific approach begins with an attitude of skepticism — a willingness to question accepted beliefs, expressed by René Descartes in 1637 as a determination "never to accept anything for true which I did not clearly know to be such". The English philosopher Francis Bacon (1561-1626), often described as the pioneer of the modern scientific method, proposed that scientists should "empty their minds" of self-evident truths and, by observation and experimentation, should draw general conclusions by a process known as induction.[19] Bacon described many of the commonly accepted principles of scientific method, but recognised that to interpret nature, something more than observation and reason is needed:

...the universe to the eye of the human understanding is framed like a labyrinth, presenting as it does on every side so many ambiguities of way, such deceitful resemblances of objects and signs, natures so irregular in their lines and so knotted and entangled. ... No excellence of wit, no repetition of chance experiments, can overcome such difficulties as these. Our steps must be guided by a clue...[20]

The 'something more' that is needed comes from imagination and intuition, guided by reason and understanding. Scientists make ambitious 'leaps' to envisage possible explanations that make sense of what we see. Classically, the scientific method has thus been broken into basic facets that start with observations of nature and how it behaves and then making a prediction about how it might behave under different circumstances. Scientists propose a hypothesis and, by experiments test it by eliminating any plausible alternatives in a process of falsification. Other scientists join in the process of hypothesis testing, while at the same time developing new hypotheses that seek to explain more and more, thereby building a foundation of knowledge that they call science. However all of this is guided by theory — a framework of accepted knowledge and understanding that guides our choice of questions to ask, guides our choices about how to go about answering those question, and guides our interpretation of the results of those experiments. This theoretical framework that captures what we think we already know is what provides the clues to know more. When we are mistaken in what we think we know, however, everything that we build on those foundations becomes unsafe, and when a new theory emerges much of what we thought we had learned has to be interpreted afresh. New theories are therefore embraced only with reluctance, only as a last resort, because of the inevitable disruption that entails.

Hypotheses

The man of science must work with method. Science is built up of facts, as a house is built of stones; but an accumulation of facts is no more a science than a heap of stones is a house. Henri Poincaré, mathematician and philosopher (1854-1912)[21]

The philosopher Karl Popper (1902-1994), in The Logic of Scientific Discovery [22] argued that the 'Baconian' process of induction — of gathering facts, considering them, and inferring general laws — is logically unsound, as many mutually inconsistent hypotheses might be consistent with any given facts.[23] Rather, Popper argued that the good scientist begins with a bold speculation, a hypothesis, from which he logically deduces predictions that can be tested by experiments. Experiments are not designed to confirm or verify the hypothesis, quite the contrary, they are designed to test the hypothesis, by attempting to disprove it. He argued that this 'hypothetico-deductive' method was the only sound way by which science makes progress, and concluded that for a proposition to be considered scientific, it must, at least in principle, be possible to make an observation that would show it to be false. Otherwise, the proposition has, as Popper put it, no connection with the real world.

Responses to Popper: Thomas Kuhn and the Science Wars

Popper's views were in marked contrast to those of his contemporary, Thomas Kuhn (1922-1996). Kuhn's own book The Structure of Scientific Revolutions was as influential as Popper's, but its message was very different. Kuhn analysed 'scientific revolutions' — times in the history of science when one dominant theory was replaced by another, such as the replacement of Ptolemy's geocentric model of the Universe with the Copernican heliocentric model, and the replacement of Newtonian laws of motion with Einstein's theory of Relativity.

While in many respects, Popper seemed to be making flat assertions about 'good science', Kuhn attempted to work as a sociologist, and to report what scientists actually did. At least initially in his career, he believed in some form of scientific progress.

Kuhn divided scientific development (to avoid the word 'progress') into two phases, times of normal science and times of paradigm shift. A paradigm is a logically consistent set of ideas that guides and constrains the work that scientists do. Scientific research conducted in accordance with a dominant paradigm is called normal science. A paradigm shift occurs when a radical change occurs in the fundamental beliefs scientists hold about their field of study.

Kuhn concluded that falsifiability had played almost no role in scientific revolutions. He argued that scientists working in a field resist the alternative interpretations of 'outsiders', and tenaciously defend their world view by continually elaborating their shared theory; "normal science often suppresses fundamental novelties because they are necessarily subversive of its basic commitments".

According to Kuhn, most progress is made in a scientific field when one theory is dominant. Progress occurs by the "puzzle solving" of scientists who are not trying to challenge the accepted theory, but are trying to extend its scope and explanatory power, bringing theory and fact into closer agreement by a "strenuous and devoted attempt to force nature into the conceptual boxes supplied by professional education".[24]

After the publication of 'The Structure of Scientific Revolutions' in 1962, Kuhn's revolution expanded. In the 1960s and 1970s, the academy (particularly in America) was in ferment. The development of radical and Marxist theory combined with political frustrations, and gave rise to a generation of academics who were deeply dissatisfied with the central narratives of American life, including scientific progress. Many of these academics latched on to Kuhn's ideas (and sometimes just his slogans) as a natural fit with their own ideas.

This frustration with mainstream science took a series of forms. In the 1970s, the conflict began with early skirmishes about intelligence testing and the small-scale, though ferocious, battle over sociobiology. (It is worth noting that the sociobiology affair remained primarily a dispute within science) The partisans of the sociobiology debate continued their struggle into the 1980s. In the 1990s, scholars from the humanities and social sciences launched an assault on the central beliefs of science in what came to be known, somewhat hyperbolically, as the science wars.

Theories

The three Laws of Thermodynamics can be expressed in many different ways[25]
Zeroeth Law: When two objects are separately in thermodynamic equilibrium with a third object, they are in equilibrium with each other.
First Law (Principle of Conservation of Energy): Between any two equilibrium states, the change in internal energy is equal to the difference of the heat transfer into the system and work done by the system.
Second Law (Carnot's Principle): A natural process that starts in one equilibrium state and ends in another will go in a direction that causes the entropy of the system plus the environment to increase for an irreversible process and to remain constant for a reversible process.

A scientific theory[26] is an overarching world view in an area of science. A theory may include statements of general scientific laws, such as the Laws of Thermodynamics, it has a logical structure and includes axioms and defined concepts, and broadly it seeks to provide a coherent explanation of a large body of observations, and to bind these together with a set of related hypotheses. Theories are a necessary part of science because they determine a common language by which scientists in a field can communicate — communication of ideas depends upon scientists sharing key assumptions and using a common terminology. A particular theory is adopted by a scientific community for complex reasons; theories are preferred when they are successful in explaining a wide body of observations, but also when they are elegant, aesthetically satisfying in a way that is hard to define. This is sometimes expressed as a preference for simple, clear explanations. In the 14th century, the English logician and Franciscan friar William of Ockham formulated the 'law of parsimony', commonly known as 'Ockham's razor' — "entities should not be multiplied more than is needed" (in Latin, entia non sunt multiplicanda praeter necessitatem).

An example of a current theory is the Theory of Evolution by Natural Selection. This seeks to explain the characteristics of all currently living organisms as the products of evolution, acting mainly by natural selection of organisms for reproductive success. The foundation of this theory is that, within any single species, individuals differ in the exact composition of their genes. These differences arise because of spontaneous random mutations in the genes, and because, in sexually reproducing organisms, every organism will inherit a different combination of genes from their parents, and because, independently of sexuality, there are mechanisms for generating novel genes by rearrangement of existing genes, and mechanisms for changing the way a gene functions. These processes for generating inheritable novelty produce differences in the traits of the individual organisms which can mean that some individuals are more likely to survive and reproduce than others, so the particular genes that they carry are more likely to be propagated in the next generation. Over time, beneficial genes — those that confer advantages to the individuals that carry them — will accumulate in a population, and maladaptive genes will be eliminated. Accordingly, over many generations, the characteristics of a population will change — the population will evolve. Eventually, in some circumstances, such as when a population is geographically isolated and subject to different environmental challenges, this can give rise to a new species.

It is not in the scope of this article to explain this theory fully or to defend it, but here we simply note a few features of this theory that are common to all theories. First, the theory explains a very large body of knowledge — the origin of the characteristics of all living things. Second, the theory involves presumptions: in this case, one presumption is that no intelligent creator directs the process of evolution. The theory cannot contradict the thesis that there is such an intelligent creator, it only declares that it is not necessary to invoke the existence of an intelligent creator to explain evolution. The theory does give an explanation for how living systems emerged from the non-living world. Third, the theory gives rise to hypotheses and to predictions. One hypothesis is that all life arises from common ancestors, and a prediction from this is that the genes of different species will show evidence for this, in that the genes that characterise different species will differ by a degree that is related to the time when the fossil record tells us that the species diverged. Fourth, the theory has undergone continual development and embellishment since it was first articulated by Charles Darwin, indeed the theory was proposed when virtually nothing was known of genes.

The Theory of natural selection is generally regarded as one of the 'cornerstones' of modern biology, but in a strict sense it is difficult to see it as falsifiable. It is accepted less because of the weight of experimental evidence, or because of its success in withstanding attempted disproof, but because of aesthetic considerations. In its essence it is seductively simple, and the force of its logic makes it seem self evidently true to contemporary biologists; it has a sweeping power to explain many diverse things, and it has succeeded, despite its simplicity, in stimulating many important ideas about the mechanisms underlying genes, their functions and their mechanisms of inheritance.

To say that the Theory is generally accepted is not to say that biologists are fully in agreement with each other; they are not, there is considerable debate and disagreement about many aspects of the Theory, especially about which of the many mechanisms of natural selection are most important. There are also alternatives, notably the Theory of Intelligent Design. This theory is based on the conclusion of its proponents that natural selection alone is incapable of explaining the evolution of highly complex organisms, and it postulates that some intelligence must have been involved in their design. The theory of Intelligent Design is accepted by very few biologists; most do not agree that the theory of natural selection cannot account for the complexity of living creatures, and so regard the concept of an intelligent designer as in breach of Ockham's razor.

For Popper, no theory can ever be shown to be true - a theory may be corroborated by evidence, but can never be verified. He regarded the old scientific ideal of certain, demonstrable knowledge as illusory: that we can be certain about our faith, but scientific statements are forever in doubt. It is not possession of knowledge that makes the "man of science", but the "persistent and reckless quest for truth." In his words:

Science does not rest upon solid bedrock. The bold structure of its theories rises, as it were, above a swamp. It is like a building erected on piles...if we stop driving the piles deeper, it is not because we have reached firm ground. We simply stop when we are satisfied that the piles are firm enough to carry the structure, at least for the time being. (Popper, K (1959) The Logic of Scientific Discovery)

The scientific method in practice

While scientists disagree among themselves and between themselves about whether there is a general "scientific method" and if so exactly what it involves, in any given field there are always some practices that are accepted as scientific good practice and others that are not. When scientists give expert evidence in Courts of Law, their evidence is given particular weight, reflecting the respect that is given to good scientific practice. In 1993, in the Daubert v. Merrell Dow Pharmaceuticals decision, the U.S. Supreme Court accorded a special status to 'The Scientific Method', in ruling that "… to qualify as 'scientific knowledge' an inference or assertion must be derived by the scientific method. Proposed testimony must be supported by appropriate validation - i.e., 'good grounds', based on what is known." The Court also stated that "A new theory or explanation must generally survive a period of testing, review, and refinement before achieving scientific acceptance. This process does not merely reflect the scientific method, it is the scientific method."[27]

The UK Research Charity Cancer Research UK gives an outline of the scientific method, as practised by their scientists[28].

Hypotheses

It is always safe and philosophic to distinguish, as much as is in our power, fact from theory; the experience of past ages is sufficient to show us the wisdom of such a course; and considering the constant tendency of the mind to rest on an assumption, and, when it answers every present purpose, to forget that it is an assumption, we ought to remember that it, in such cases, becomes a prejudice, and inevitably interferes, more or less, with a clear-sighted judgment. I cannot doubt but that he who, as a wise philosopher, has most power of penetrating the secrets of nature, and guessing by hypothesis at her mode of working, will also be most careful, for his own safe progress and that of others, to distinguish that knowledge which consists of assumption, by which I mean theory and hypothesis, from that which is the knowledge of facts and laws; never raising the former to the dignity or authority of the latter, nor confusing the latter more than is inevitable with the former.
—Michael Faraday[29]

[Scientists] start by making an educated guess about what they think the answer might be, based on all the available evidence they have. This is known as forming an hypothesis.[30]

A hypothesis is a proposed explanation of a phenomenon. It may be an “inspired guess”, a “bold speculation”, embedded in current understanding yet going beyond that to assert something that we do not know for sure as a way of explaining something not otherwise accounted for. Most importantly, a scientific hypothesis is something that has consequences, it leads to predictions and these can be tested by experiments. If the predictions prove wrong, the hypothesis is discarded, otherwise it is put to further test. If it resists determined attempts to disprove it, then it might come to be accepted, at least for the moment, as 'true'.

Scientists use many different means to generate hypotheses, including their own creative imagination, ideas from other fields, and by induction. Charles Sanders Peirce (1839-1914) described the incipient stages of inquiry, instigated by the "irritation of doubt" to venture a plausible guess, as abductive reasoning [31]. The history of science is full of stories of scientists claiming a "flash of inspiration" which motivated them. One of the best known is from the chemist August Kekulé (1829-1896), who proposed that structure of molecules followed particular rules. Kekulé recounted that the structure of benzene came to him in a dream, in which rows of atoms wound like serpents before him; one of the serpents seized its own tail: "the form whirled mockingly before my eyes. I came awake like a flash of lightning. This time also I spent the remainder of the night working out the consequences of the hypothesis".[32]

Experiments and observations

Researchers carry out carefully designed studies, often known as experiments, to test their hypothesis. They collect and record detailed information from the studies. They look carefully at the results to work out if their hypothesis is right or wrong…

An experiment is a procedure carried out under controlled conditions to gain new information or better understanding. Not all science involves experimentation; for example the human genome project largely involves (highly technical) interpretation of gene sequences, but the data were obtained by experimental investigation. Equally, not all experiments are designed to test hypotheses; some extend our knowledge by making more detailed observations of known phenomena, or by exploring new or unexplained phenomena more fully.

Between 1907 and 1917, the theoretical physicist Albert Einstein (1879-1955) developed the General theory of relativity, which, amongst other things, explains gravitation as a manifestation of curvature of space and time. Several predictions can be derived from Einstein's theory of General Relativity, and one prediction was that light will appear to 'bend' in a gravitational field by an amount that depends on the strength of the field. Arthur Eddington (1882-1994) devised experiments to test this prediction; his observations, made during a solar eclipse in 1919, supported General Relativity and showed the restrictions in applicability of the accepted theory of gravitation, credited to Isaac Newton (1643-1727).

Werner Heisenberg (1901-1976) was one of the physicists responsible for developing the theory of quantum mechanics (which so far resisted logical unification with general relativity). In a quote that he attributed to Albert Einstein, he stressed how observations depend upon the theories that are held at the time they are made [33] "The phenomenon under observation produces certain events in our measuring apparatus. As a result, further processes take place in the apparatus, which eventually and by complicated paths produce sense impressions and help us to fix the effects in our consciousness. Along this whole path—from the phenomenon to its fixation in our consciousness—we must be able to tell how nature functions, must know the natural laws at least in practical terms, before we can claim to have observed anything at all. Only theory, that is, knowledge of natural laws, enables us to deduce the underlying phenomena from our sense impressions."

For Karl Popper, theory was profoundly important in science; a theory encompasses the preconceptions by which the world is viewed, and defines what we choose to study, and how we study it and understand it. He recognised that theories are not discarded lightly, and a theory might be retained long after it has been shown to be inconsistent with known facts (anomalies). However, the recognition of anomalies drives scientists to adjust the theory, and if the anomalies continue to accumulate, will drive them to develop alternative theories. Popper proposed that a theory should be judged by the extent to which it inspires testable hypotheses. While theories always contain many elements that are not falsifiable, Popper argued that these should be as few as possible. However, scientists also seek theories that are "elegant"; a theory should yield clear, simple explanations of complex phenomena, that are intellectually satisfying in being logically coherent, rich in content, and involving no miracles or other supernatural devices.

Peer review

…Once they have completed their study, the researchers write up their results and conclusions. And they try to publish them as a paper in a scientific journal. Before the work can be published, it must be checked by a number of independent researchers who are experts in a relevant field. This process is called ‘peer review’, and involves scrutinising the research to see if there are any flaws that invalidate the results…

The main way of disseminating scientific information is through the peer-reviewed scientific literature. This is a vast array of academic journals that was once mainly restricted to the libraries of Universities and research institutes, but these are now mostly available on-line through the internet, and often they are freely available. There are many thousands of these journals, some of which are managed and owned by scientific societies, others by commercial publishers. The better scientific journals publish just a small proportion of the manuscripts submitted to them, and only after a process of peer review and revision. An article published in the peer-reviewed literature that describes the outcome of a series of experiments is known as a 'scientific paper'. Over their careers, many scientists may publish more than a hundred such papers, but even for the most successful scientists very few of their papers have a major, lasting influence. Some scientists have achieved wide acclaim despite publishing very few papers, because of the exceptional importance of those few. One measure of the influence of a paper is how often it is 'cited' — referenced in other scientific papers. As most scientific papers include references to about 30 other papers, an average paper will eventually accrue about 30 'citations'. Frederick Sanger, twice winner of the Nobel Prize for Chemistry (1958 and 1980)[34] published about 70 papers in his whole career; 30 of these have been cited more than 100 times each, and four of them more than 1000 times each.

Manuscripts submitted for publication in scientific journals are normally sent by the editor to (usually one to three) other scientists for evaluation. These 'expert referees' advise the editor about the suitability of the paper for publication in the journal. They also report, usually anonymously, on its strengths and weaknesses, pointing out any errors or omissions that they noticed and offering suggestions for how the paper might be improved by revision or by further experiments. With this advice, the editor might reject the paper or decide that it might be acceptable if appropriately revised.

Peer review has been widely adopted by the scientific community, but has weaknesses. It is easier to publish data that are consistent with a generally accepted theory than data that contradict it. This helps to ensure the stability of the accepted theory, but also means that the appearance of the extent to which a current theory is supported by evidence might be misleading — boosted by a poorly scrutinised supportive work while insulated from criticism. The biologist Lynn Margulis encountered great difficulty in publishing her theory that the eukaryotic cell is a symbiotic union of primitive prokaryotic cells. In 1966, she wrote a theoretical paper entitled The Origin of Mitosing Cells; it was "rejected by about fifteen scientific journals," as Margulis recalled. Finally accepted by The Journal of Theoretical Biology, it is now considered a landmark in modern endosymbiotic theory.[35] In 1995, Richard Dawkins said, "I greatly admire Lynn Margulis's sheer courage and stamina in sticking by the endosymbiosis theory, and carrying it through from being an unorthodoxy to an orthodoxy." [36]

To the defense of the possible conservatism of reviewers, it must be remarked that they must trust at face value the experimental data that are in the manuscript before them. They cannot repeat the experiments and verify their outcome—they lack the time and often the possibility. All a reviewer can do is decide whether experimental data look "reasonable", which implies a judgment about the plausibility of the data in the light of the ruling paradigm. There are some famous cases of fraud that took years before unveiling, mainly because the fraud took care that his/her faked results looked "reasonable". Conversely, experimental data and theories that look "unreasonable" (in contradiction with the dominant paradigm) may need a long time (and affirmation by different laboratories) before they are deemed publishable. Notorious is the affair around the publication of Benveniste's "unreasonable" experimental data on the memory of water in Nature.

The scientific literature

…If the study is found to be good enough, the findings are published and acknowledged by the wider scientific community…

The way in which scientific research is presented in published form is governed by sometimes quite rigid conventions. Although they differ slightly from one field to another, a scientific paper generally has an 'Introduction', which gives a brief background to the question that is being addressed, a 'Methods' section, which details the experimental procedures in enough detail to allow them to be replicated independently, a 'Results' section which objectively details the findings, and a 'Discussion' section in which the authors interpret the findings and relate them to other work.

Peter Medawar (1915-1987), Nobel laureate in Physiology and Medicine, in his article “Is the scientific paper a fraud?” [37] argued that the scientific paper in its orthodox form embodies "a totally mistaken conception, even a travesty, of the nature of scientific thought." Because the results of an experiment are interpreted only at the end (in the discussion section) of scientific papers, this gives the impression that those conclusions are drawn by induction or deduction from the reported evidence. However, explains Medawar, it is the expectations that a scientist begins with that provide the incentive for the experiments, determine their nature, and determine which observations are relevant and which are not. Only in the light of these initial expectations do the activities described in a paper have any meaning at all. The expectation, the original hypothesis, according to Medawar, is not the product of inductive reasoning but of inspiration — educated guesswork.

Confirmation

…But, it isn’t enough to prove a hypothesis once. Other researchers must also be able to repeat the study and produce the same results, if the hypothesis is to remain valid…

Sometimes scientists make errors in the design, execution or analysis of their experiments, so it is common for other scientists to try to repeat experiments, especially when the results were surprising. [38] Accordingly, scientists keep detailed records of their experiments, to provide evidence of their effectiveness and integrity and assist in reproduction. Generally, in publishing their work, it is considered essential that scientists describe their methods in enough detail to allow them to be repeated by others. However, a scientist cannot record everything about an experiment; he (or she) reports what he believes to be relevant. This can cause problems if some supposedly irrelevant feature is questioned. For example, Sidney Ringer's experiments with isolated frog hearts first led him to declare that the heart could continue to beat if kept in a simple saline solution. However, he later discovered that the solution had been made up not with distilled water but with London tap water, which contained a significant amount of calcium carbonate. He retracted his first reports, and is now known as the scientist who showed that calcium is important for the contractions of the heart. [39]

Statistics

…If the initial study was carried out using a small number of samples or people, larger studies are also needed. This is to make sure the hypothesis remains valid for bigger group and isn't due to chance variation…

Scientists analyse their data using the theory and methods of Statistics, which arose from probability theory. Statistical analysis essentially involves methods for drawing conclusions from data that involve multiple sources of error.

Statistical analysis is a part of hypothesis testing in many areas of science. This formalises the criteria for disproof by allowing statements of the form: "If our hypothesis is true, the chance of getting the results that we observed is (say) only 1 in 20 or less (P < 0.05); therefore the hypothesis is probably wrong, and so we reject it. For instance, we might predict that a given chemical will produce a certain effect. However what we often test is not this, but the null hypothesis - that the chemical will have no effect. The reason is that, if our original hypothesis is vague about how big an effect to expect, then we cannot disprove it, as we can't exclude the possibility that the effect is too small to measure. However, we can disprove the null hypothesis (by showing an effect). Ideally, we choose hypotheses that give precise predictions, but this is often unrealistic. In medicine for example, we might expect a new drug to be effective in a particular condition from our understanding of its mechanism of action. Even so, we might not know how big an effect to expect because of many uncertainties - how many people will be resistant to the drug? for example, and how quickly will tolerance to the drug develop in people who respond well?

This is not hypothesis testing in Popper's sense, because the hypothesis is not put at any hazard of disproof. Verification of this type is something that Popper considered to be, at best, weak corroborative evidence, partly because it is impossible to measure the support that such evidence provides. [40]

In the 18th century, an English clergyman, Thomas Bayes (1702-1761) proved a result, now known as Bayes Theorem, that, in some interpretations, provides a formal method for revising beliefs in the light of new evidence [41]. It has been argued that Bayesian statistics can be used to provide a basis for support by induction, and some areas of science use these approaches. Bayesian statistics measures how the probability that a hypothesis is true changes as a result of observations, but it depends on assigning initial values to the probabilities of alternative outcomes of an experiment. This is not always possible because of the difficulty of assigning these a priori probabilities in any meaningful way.

Progress and controversy in science

...Over time, scientific opinion can change. This is because new technologies can allow us to re-examine old questions in greater detail.

Although skepticism, or doubt, has long been recognised as an important element in all science, Kuhn argued that scientific opinion does not change easily in fundamental things. In particular, one theory or world view is replaced by another not because many scientists are 'converted' to the new world view. Instead, a new theory begins as an unfashionable alternative that is often derided, but gains adherents as its advantages become apparent to new scientists entering the field, while the adherents of the old view fight a 'rear-guard action' to defend it. Barbara McClintock's work on regulatory elements that control gene expression won her the Nobel Prize in Physiology or Medicine in 1983, but in 1953 she decided to stop trying to publish detailed accounts of her work, because of the puzzlement and hostility of her peers. In 1973 she wrote:

"Over the years I have found that it is difficult if not impossible to bring to consciousness of another person the nature of his tacit assumptions when, by some special experiences, I have been made aware of them. ...One must await the right time for conceptual change"[42]

Kuhn focused attention on the unexplainable phenomena as the key to scientific revolutions, which he called "paradigm shifts". One example reported in The Structure of Scientific Revolutions dates back to the mathematical astronomer Claudius Ptolemy, who lived in Egypt in the 2nd century CE. The improvements in astronomical observation, and the accumulation of more data during that time required more and more elaborate explanations to reconcile the observational data with the accepted belief that the earth was the centre of the solar system, and indeed of the universe. By the time of Copernicus (1473-1543), so much evidence had accumulated suggesting that the sun was in fact the center of the solar system, the whole infrastructure of theories broke down, leading the way to acceptance of a new heliocentric world picture. Yet, it took more than a century before all astronomers were convinced. When Einstein showed in 1905 that there is no ether, or at least that the concept is superfluous and may be removed from physics by Ockham's razor, many of the older generation of physicists did not accept this paradigm shift and died believing in ether; they were not converted, the ether concept died out.

New observations about natural phenomena continue to lead to such revolutions in biology, plate tectonics, particle physics, and many other branches of science.

Alternative views

"The progress of science is often affected more by the frailties of humans and their institutions than by the limitations of scientific measuring devices. The scientific method is only as effective as the humans using it. It does not automatically lead to progress." Steven S. Zumdahl

The success of science, as measured by the technological achievements that have changed our world, have led many to conclude that this success is because of the methodological rules that scientists follow. However, not all philosophers accept this conclusion; for example, Paul Feyerabend (1924-1994) denied that science is genuinely a methodological process. In his book Against Method he argued that scientific progress is not the result of applying any particular rules.[43] Instead, he concluded almost that 'anything goes', in that for any particular 'rule' there are abundant examples of successful science that have proceeded in a way that seems to contradict it.[44] To Feyeraband, there is no real difference between science and other areas of human activity characterised by reasoned thought. A similar sentiment was expressed by T.H. Huxley in 1863: "The method of scientific investigation is nothing but the expression of the necessary mode or working of the human mind. It is simply the mode at which all phenomena are reasoned about, rendered precise and exact."[45]

Some scientists focus their activity on making precise and detailed observations of a phenomenon, gathering data, organizing it in sensible ways, making it accessible to other scientists. We do not disqualify those scientists as ‘scientists’ on the grounds they do not employ a scientific method. Other scientists might use their observational data to generate testable hypotheses, and other scientists might test those hypotheses by experiment, and others try to reproduce the findings. That illustrates an instance of the scientific method in action realized by the combined effort of two or more scientists working with different methods, not necessarily in one generation. Regardless of the hopefully rational approach that each scientist employs in her 'scientific method', none can leave their biases and passions outside their mind. Sometimes biases and passions contribute the advancement of science. The scientific method is the endeavor of humans, prone to error for many reasons, prone to creative insights by nature. But scientists agree on the need for verifiable knowledge, and they cannot suppress the emergence of new perspectives and paradigms.

In his 1958 book, Personal Knowledge, the chemist and philosopher Michael Polanyi (1891-1976) criticized the view that the scientific method is purely objective and generates objective knowledge. Polanyi thought that this was a misunderstanding of the scientific method, and argued that scientists do and must follow their passions in appraising facts and in choosing which questions to investigate. He concluded that a structure of liberty is essential for the advancement of science — that the freedom to pursue science for its own sake is a prerequisite for the production of knowledge.[46]

The changing nature of science

Charles Darwin was an amateur scientist, a man of independent means and broad ranging interests who worked to satisfy his own curiosity. Still in the early 20th century, science was the province of individuals with wide interests. Albert Einstein was working as clerk in a patent office in Bern in 1905, the year that he published four papers in Annalen der Physik that are now each recognised as hugely important; the four papers discuss the particulate nature of light; Brownian motion; the theory of special relativity; and the equivalence of matter and energy.

In the 20th century, science became largely professionalised, conducted increasingly by specialised experts employed in Universities or research institutes, and increasingly governed by the priorities of funding bodies, which in turn have become increasingly influenced by the political priorities of the Governments that are the source of the funding for research.

The 'lone scientist' is now a rare animal; most science is now a collaborative enterprise, often conducted in large teams where each member of the team supplies a specific area of specialised expertise. Most of Frederick Sanger's scientific papers, published between 1945 and 1980, were either authored by him alone or with just one other co-author. This is now unusual in the Life Sciences, where most papers have several authors and many have ten or more. In experimental high-energy physics, papers with more than 100 authors from 40 or more institutions are the rule.[47]

Increasingly, scientists work towards specified ambitious goals; a prime example is the Human Genome Project, a research program involving hundreds of laboratories across many countries directed at sequencing the entire human genome. This 13-year project, coordinated by the U.S. Department of Energy and the National Institutes of Health, was completed in 2003.

Thus the 20th century saw a transition from curiosity-driven research to hypothesis-driven research and then to goal-directed research. These changes were accompanied by major changes in the sociology of the scientific community. Research scientists today mostly have a very narrowly specialised technical expertise, are professionally employed, funded directly or indirectly by Governments, research charities or industry, and generally work within a team that may be part of a multinational network of teams working to a common goal.

Notes and references

  1. Isaac Newton (1643-1727) The Rules of Reasoning in Philosophy Excerpts in: The Mathematical Principles of Natural Philosophy. Source: Modern History Sourcebook
  2. Full-Text: Newton's Principia: The Mathematical Principles of Natural Philosophy (c1846), including BOOK III. RULES OF REASONING IN PHILOSOPHY
  3. Leng G, MacGregor DJ. (2008) Mathematical Modelling in Neuroendocrinology. Journal of Neuroendocrinology: From Molecular to Translational Neurobiology 20:713-718.
    • Excerpt: Our science is not only about facts, but also about explanations; rational accounts of phenomena, embedded in a framework of theory, which include a wide range of observations and which are predictive of behaviour in circumstances as yet untested. We all seek to explain the world of observations using a set of logically interacting components, and we all simplify by recognising that some observations are important while others can be reasonably neglected. Formulating such explanations mathematically is a natural ambition, because this ensures their logical consistency, and makes them open to structured analysis; it is a stringent test of their intellectual coherence.
  4. Citizendium Collaborators. (2009) Biology’s Next Microscope: Mathematics. Citizendium Free Online Encyclopedia.
    • Excerpt: Mathematics broadly interpreted is a more general microscope. It can reveal otherwise invisible worlds in all kinds of data, not only optical….Charles Darwin was right when he wrote that people with an understanding “of the great leading principles of mathematics... seem to have an extra sense”….Today’s biologists increasingly recognize that appropriate mathematics can help interpret any kind of data. In this sense, mathematics is biology’s next microscope, only better.
  5. Ferris T. (1988) Coming of Age in the Milky Way. New York: Morrow, ISBN 0688058892. | Google Books preview, 2003 edition.
  6. According to the logical positivist philosopher Rudolf Carnap, philosophers and scientists use the term 'observable' in different ways. To philosophers, 'observable' applies to properties that are directly perceived by the senses, such as "blue", "hard" and "hot". To scientists, the word includes anything that can be measured relatively simply and directly. Carnap R (1966)Theories and Nonobservables from Philosophical Foundations of Physics Basic Books, ASIN B0000CN9NI
  7. Theory-ladenness by Paul Newall at The Galilean Library
  8. Darwin CR. (1861) Letter 3257 — Darwin, C. R. to Fawcett, Henry, 18 Sept (1861)
    • Note: Darwin understood the point. Excerpt from the letter to Fawcett: “About thirty years ago there was much talk that geologists ought only to observe and not theorise; and I well remember some one saying that at this rate a man might as well go into a gravel-pit and count the pebbles and describe the colours. How odd it is that anyone should not see that all observation must be for or against some view if it is to be of any service!”” [Emphasis added]
  9. For Aristotle, science was the product of reason applied to careful observations; Galileo Galilei by contrast used experiments as a way to interrogate Nature.
  10. Dowe, Phil. (Fall 2008 Edition) Causal Processes. The Stanford Encyclopedia of Philosophy. Edward N. Zalta.
  11. Woodward, James. (Spring 2009 Edition) Scientific Explanation. The Stanford Encyclopedia of Philosophy. Edward N. Zalta (ed.).
  12. Note: Regarding 'skeptical open mindedness', to paraphrase space engineer, James Oberg, open mindedness confers virtue unless it so opens the mind that one's brains fall out. (Cited by Carl Sagan, in The Demon-Haunted World: Science as a Candle in the Dark. Ballantine Books: New York, 1997. Preview Sagan's book at Google Books here.)
    • Excerpt: Keeping an open mind is a virtue — but, as the space engineer James Oberg once said, not so open that your brains fall out. Of course we must be willing to change our minds when warranted by new evidence. But the evidence must be strong. Not all claims to knowledge have equal merit. (Page 187)
  13. Medawar P (1982) Pluto's Republic, Oxford University Press ISBN 0192830392; read a review here
  14. Hall MP. The Four Idols of Francis Bacon: The New Instrument of Knowledge.
    • "In the Novum Organum (the new instrumentality for the acquisition of knowledge) Francis Bacon classified the intellectual fallacies of his time under four headings which he called idols. He distinguished them as idols of the Tribe, idols of the Cave, idols of the Marketplace and idols of the Theater…An idol is an image, in this case held in the mind, which receives veneration but is without substance in itself. Bacon did not regard idols as symbols, but rather as fixations."
  15. Fantini F. (2005) Didattica dell'evoluzione. In Evoluzione tra ricerca e didattica, XIV – Special number Edited by: Associazione Nazionale Insegnanti di Scienze Naturali. Agnano Pisano: Stamperia Editoriale Pisana; 2005:203-209.
  16. Guidetti R, Baraldi L, Calzolai C, Pini L, Veronesi P, Pederzoli A. (2007) Fantastic animals as an experimental model to teach animal adaptation. BMC Evolutionary Biology 7(Suppl 2):S13 doi: 10.1186/1471-2148-7-S2-S13.
  17. Scanning Tunneling Microscope at the Nobel Foundation's website
  18. From the autobiography of Charles Darwin, available online.
  19. Bacon, Francis (1620) Novum Organum (The New Organon)
  20. from Preface to The Great Instauration; 4.18 quoted in Pesic P (2000) The Clue to the labyrinth: Francis Bacon and the decryption of nature Cryptologia. Francis Bacon should not be confused with Roger Bacon (ca 1214-1294), a Franciscan friar who also has claims to be a pioneer of observation and experiment, and who was imprisoned when his work challenged the dogma of the Church.
  21. Henri Poincaré (1905). Science and Hypothesis. London: Walter Scott Publishing.
  22. Popper K (1959) The Logic of Scientific Discovery (Translation of Logik der Forschung). The Nobel prize winner Sir Peter Medawar called this book "one of the most important documents of the 20th century"
  23. Vickers, J (2006). The Problem of Induction (Stanford Encyclopedia of Philosophy). Stanford Encyclopedia of Philosophy. Retrieved on 2007-11-16.
  24. Kuhn TS (1961) The Function of Measurement in Modern Physical Science ISIS 52:161–193
    • Kuhn TS (1962)The Structure of Scientific Revolutions University of Chicago Press, Chicago, IL. 2nd edition 1970, 3rd edition 1996
    • Kuhn TS (1977) The Essential Tension, Selected Studies in Scientific Tradition and Change University of Chicago Press, Chicago, IL
    • A Synopsis from the original by Professor Frank Pajares, From the Philosopher's Web Magazine
    • Moloney DP (2000) First Things 10153-5
  25. these examples are given as on a NASA web site
  26. In science, the term "theory" indicates a logically connected set of hypotheses supported by a significant body of evidence. In daily life the term is used as in "that's just your theory", a hunch which may or may not be correct. This difference in meaning leads to miscommunication between scientists and laypersons, see: Helen Quinn, Belief and knowledge—a plea about language, Physics Today, January 2007.
  27. Text of the opinion, LII, Cornell University; Daubert-The Most Influential Supreme Court Decision You've Never Heard of
  28. Science fact or fiction?, from Cancer Research UK
  29. Faraday M. (1844) Experimental Researches in Electricity. Volume 2. Richard and John Edward Taylor, printers and publishers to the University of London. | Google Book full-text.
    • "It is always safe and philosophic to distinguish...", pp. 285-286.
  30. This quote and the ones that follow are from the Cancer Research UK outline.
  31. Charles Sanders Peirce entry at the Stanford Encyclopedia of Philosophy
  32. cited in Bargar RR, Duncan JK (1982) Cultivating creative endeavor in doctoral research J Higher Educ 53:1-31 doi
  33. Heisenberg, Werner (1971) Physics and Beyond, Encounters and Conversations, A.J. Pomerans (trans.), Harper and Row, New York, NY pp.63–64
  34. 1958 Nobel Prize for Chemistry and 1980 Nobel Prize for Chemistry)
  35. Sagan L (1967) On the origin of mitosing cells" J. Theor Biol 14:255-74 Abstract
  36. John Brockman, The Third Culture, New York: Touchstone 1995, 144
  37. Medawar, P. B. “Is the scientific paper a fraud?”, BBC Third Programme, Listener 70, 12 September 1963.
  38. Georg Wilhelm Richmann was killed by lightning in 1753 when attempting to replicate the kite experiment of Benjamin Franklin. Krider P (2006) Benjamin Franklin and lightning rods Physics Today 59:42, available online
  39. Carafoli E (2002) Calcium signalling: a tale for all seasons PNAS USA 99:115-22
  40. In appendix ix to The Logic, Popper states: "As to degree of corroboration, it is nothing but a measure of the degree to which hypothesis h has been tested...it must not be interpreted therefore as a degree of the rationality of our belief in the truth of h...rather it is a measure of the rationality of accepting, tentatively, a problematic guess."
  41. Bellhouse DR (2004) The reverend Thomas Bayes FRS: a biography to celebrate the tercentenary of his birth Statistical Science 19:3-43
  42. McClintock B (1987) The discovery and characterization of transposable elements: the collected papers of Barbara McClintock, ed John A. Moore. Garland Publishing, Inc. ISBN 0-8240-1391-3. (Introduction)
  43. Feyerabend PK (1975) Against Method, Outline of an Anarchistic Theory of Knowledge Reprinted, Verso, London, UK, 1978; for a critical review, see "Against too much method" by John Worrall
  44. Feyerabend's 'anything goes' argument explained at the Galilean Library. Criticisms such as his led to the strong programme, a radical approach to the sociology of science.
  45. Huxley TH (1863) From a 1863 lecture series aimed at making science understandable to non-specialists
  46. Relativism entry at the Stanford Encyclopedia of Philosophy
  47. For example, see a randomly picked article in the May 2009 issue of the European Physical Journal C DOI