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Introduction

Consider this outline as an approach to defining ‘electric charge’:

  • At one level of explanation of matter, matter consists of atoms.
  • Electric charge is a property of matter manifesting in certain of the particle constituents of the atoms of matter.
  • Studying atoms at the first level of their substructure, viz., the nucleus and surrounding electrons, can provide a fruitful starting point for explaining electric charge.
  • As a starting point, note that:
    • Electrons can maintain their location surrounding and revolving about the nucleus only because a radial force of attraction on them exists directed toward the nucleus. Otherwise the electrons would fly off.
  • Experiments reveal that:
    • The force of attraction between the nucleus and electrons greatly exceeds the gravitational force generated by the masses of the two groups of particles;
    • Therefore a force differing from the force of gravitation is operating, requiring a new designation;
      • For historical reasons discussed later, we designate the force an ‘electric force’.

...the electric force is approximately 42 orders of magnitude larger than the gravitational force. To see the enormity of this ratio, suppose that we represent the gravitational force by an arrow as long as a bacterium. How long would the length of the electric arrow be? Much larger than the height of a man; much taller than the Empire State Building; much larger than the Earth itself; much larger than the solar system; and much larger than the Milky Way. In fact, the electric arrow would be over 10 billion times larger than the "size" of the visible universe! That is why, when electrical forces are present, gravitational forces can be completely ignored.[1] [2]

  • Experiments reveal also that:
    • The force of attraction occurs between the protons in the nucleus and the surrounding electrons, the two groups normally equal in number;
    • The magnitude of the electric force varies inversely with the square of the distance of separation over which the force operates.
  • Experiments reveal also that:
    • The electric force between two spatially separate protons is one of repulsion rather than of attraction;
    • The electric force between two spatially separate electrons likewise is one of repulsion rather than of attraction;
    • When separated by the same distance, the magnitude of the electric force is the same between a proton and an electron, a proton and a proton, and an electron and an electron.
  • Those experiments permit the conclusions that:
    • The electric force can be one either of attraction or repulsion;
    • Given that protons and electrons differ in mass by several orders of magnitude, the electric force does not depend on the masses of the interacting particles;
    • Therefore some quantitative property other than mass must generate and respond to the electric force between interacting particles;
      • call that property ‘electric charge’, and symbolize its unit of magnitude, q.
    • The ‘quality’ of the proton’s electric charge must differ from the ‘quality’ of the electron’s electric charge, otherwise protons and electrons could not generate and respond to either an attractive or repellent electric force depending on which interacts with which;
      • call the quality of the proton’s electric charge ‘positive’ and that of the electron’s ‘negative’, in keeping with historical designations arbitrarily assigned during the history of studies of electric phenomena on the macroscopic scale.

The convention was derived from Benjamin Franklin’s experiments. He rubbed a glass rod with silk and called the charges on the glass rod positive. He rubbed sealing wax with fur and called the charge on the sealing wax negative. Like charges repel and opposite charges attract each other.[3]

  • From the above discussion, we can formulate a provisional working definition of electric charge as follows:

Electric charge is a property of matter manifesting with an attribute of one or the other of two opposite extremes, arbitrarily referred to as positive and negative, a property of matter characteristic of certain of matter's constituent subatomic particles—specifically, protons (positive) and electrons (negative)—the property having the fundamental characteristic of producing and responding to a force of attraction between positive and negative particles, or of repulsion between positive and positive and between negative and negative particles, the force acting on spatially separated particles, that force, called the 'electric force', having a strength many orders of magnitude greater than that of the force of gravity, but like the gravitational, its strength falling in proportion to the square of the distance between the particles.

  • Atoms of the chemical elements heavier than hydrogen...

Continue in this vein....

Tentative lede to student level treatment

(PD) Diagram: Courtesy NASA/JPL-Caltech
Add image caption here.

Electric charge refers to a fundamental property of matter, a property upon which rests the numerous phenomena of electricity and electromagnetism, phenomena the particular provenance of science and engineering.

Electric charge manifests itself, in one guise, as a property of the two earliest discovered constituents of the historically conceived homogeneous and indivisible atom, namely, the subatomic particles, electrons and protons. The property of electric charge endows an electron and a proton, though spatially separate, with the ability to attract each other with a force of attraction, an electric force. The electric force of attraction between the proton and electron of a hydrogen atom gives the combination of the two charged particles its status as an atom, an atom of the chemical element, hydrogen, the lightest atom among those of all other chemical elements, whose atoms consist of more than one proton and electron.

The electric force of attraction between the two particles of the hydrogen atom differs from their gravitational force of attraction in that the magnitude of the electric force, for a given distance of separation of the two particles, exceeds by orders of magnitude the force of gravitational attraction between them associated with their masses, exceeding it ~1042 fold. For that reason, the force of attraction between an electron and a proton does not depend on the masses of the two particles, whose gravitational force can be ignored as a contributor to the magnitude of the attractive force.

...the electric force is approximately 42 orders of magnitude larger than the gravitational force. To see the enormity of this ratio, suppose that we represent the gravitational force by an arrow as long as a bacterium. How long would the length of the electric arrow be? Much larger than the height of a man; much taller than the Empire State Building; much larger than the Earth itself; much larger than the solar system; and much larger than the Milky Way. In fact, the electric arrow would be over 10 billion times larger than the "size" of the visible universe! That is why, when electrical forces are present, gravitational forces can be completely ignored.[1] [2]

For historical reasons, discussed subsequently, protons are said to be positively charged—i.e., to carry a positive electric charge—electrons, to be negatively charged—i.e., to carry a negative electric charge.

The convention was derived from Benjamin Franklin’s experiments. He rubbed a glass rod with silk and called the charges on the glass rod positive. He rubbed sealing wax with fur and called the charge on the sealing wax negative. Like charges repel and opposite charges attract each other.[3]

(PD) Diagram: Anthony.Sebastian
Add image caption here.

A non-gravitationally-mediated force also exists between two spatially separate electrons, and between two spatially separate protons, but unlike the force of attraction between an electron and a proton, the force between two electrons is one of repulsion, as is the force between two protons. Thus the electric force can mediate electric attraction or repulsion, depending on the how the types of the charges compare, hence the common expression, “like charges repel, unlike charges attract”.

Experiments performed early in the 20th century established that the magnitude of the charge carried by the electron ("cathode ray corpuscle") equals that of the proton ("the positively charged hydrogen atom"), and that the former has a mass nearly 2000 times less than that of the latter.[4] The magnitude of the electron charge, designated e, was formerly referred to as the 'elementary charge', the same for electrons and protons, despite their large mass difference. Since sensible matter consists collections of atoms, the magnitude of the net charge of a tangible substance must always be an integer multiple of e, the magnitude of the electron charge. For example, the net charge on the surface of a glass rod rubbed with a silk cloth will be positive, and the magnitude of that net charge will be an integer multiple of e, depending on the number of electrons stripped off the glass surface by the rubbing, which become attached to the surface of the silk cloth.

The terms 'positive' and 'negative' arbitrarily serve as labels to distinguish the two 'polarities', or opposing extremes, observed in the electric charge of matter. 'Positivity' and 'negativity' do not themselves imply anything about the fundamental nature of electric charge. Other labels connoting bi-polarity, such as yin/yang, black/white, or bitter/sweet, could have served for labeling, and but for historical chance, protons could carry a negative electric charge, electrons, a positive charge.

Scientists had established much of the above by the early 20th century, as evidenced from the discussion in first few chapters of the 1907 still instructively readable classic, The Corpuscular Theory of Matter, by the discoverer of the electron, Joseph John Thomson (1856-1940)[4]

References

  1. 1.0 1.1 Hassani S. (2010) [1]. In: From Atoms to Galaxies: A Conceptual Physics Approach to Scientific Awareness. Chapter 12. Boca Raton, FL: CRC Press,ISBN 9781439808498; ISBN 9781439808504 eBook-PDF.
  2. 2.0 2.1 Hassani S. (2010) From Atoms to Galaxies: A Conceptual Physics Approach to Scientific Awareness. CRC Press. Page 176. ISBN 978-1-4398-0850-4 (Ebook-PDF).
  3. 3.0 3.1 Law. MIT OpenCourseWare.
  4. 4.0 4.1 Thomson JJ. (1907) The Corpuscular Theory of Matter. New York: Charles Scribner's Sons. | Free Google eBook. | J.J. Thomson - Biography. Nobelprize.org.


Older version to be revised

Once you have established those basic ideas about electricity, "like charges repel and unlike charges attract", then you have the foundation for electricity and can build from there.
—Electric Charge, Hyperphysics Online

In reference to the physics and chemistry of electricity, charge, or more specifically, electric charge, is a fundamental property of matter that causes matter having that property to generate and react to a force of attraction or repulsion to spatially separate matter that likewise manifests the property of electric charge.[1] [2] [3]

Whatever constitutes electric charge constitutes it as two separate qualities, or polarities, assigned the names 'positive' and 'negative', or 'plus' and 'minus'. The attractive force between electrically charged entities arises between oppositely-charged entities—positive-negative—whereas the repulsive force arises between like-charged entities—positive-positive, or negative-negative.

Familiar examples of positively charged matter are protons, constituents of the nuclei of atoms, and familiar examples of negatively charged matter are electrons, constituents of atoms that surround their nuclei.

Given that the terms 'positive' and 'negative' serve only as labels to distinguish the two polarities observed in the electric charge of matter, 'positivity' and 'negativity' do not themselves imply anything about the fundamental nature of electric charge. Other labels connoting bi-polarity, such as yin/yang, black/white, or bitter/sweet, could serve for labeling.

The atoms that comprise the chemical elements of the periodic table, while consisting in part of the electrically charged particles, protons and electrons, do not themselves manifest an electric charge, because protons in the nuclei and the surrounding electrons are equal in number and quantity of charge, that balance ensuring that the atoms as a whole manifest no net electric charge—a state referred to as electrical neutrality.

Discovery and naming of electric charge

The ancient Greeks as far back as the beginning of the 6th century BCE, beginning with Thales of Miletus, had observed some of the simple phenomenology related to electric charge, Thales demonstrating it using the fossilized tree resin, amber, rubbed with cloth:[4] [5]

That little piece of amber rubbed by Thales, some 2,500 years ago, appeared then to be very insignificant. Had the world but known, it was fraught with vast possibilities; for, in point of fact, Thales had unconsciously rediscovered Aladdin's Wonderful Lamp. As he rubbed, the Genie of electricity appeared, and demanded, "What wouldst thou have? I am ready to obey thee as the slave of the lamp, I and the other slaves of the lamp." But the question remained unanswered. Neither Thales nor the witnesses of his experiment made any request nor asked its genii to aid them. They had ears, but they heard not, and so the genie disappeared, with all that he was both willing and able to do left undone.
—E.J. Houston, 1905[4]

In 600 B.C. Thales, erudite philosopher and astronomer in the thriving Ionian port of Miletus, observed the special qualities of the rare yellow orange amber, jewel-like in its hardness and transparency. If rubbed briskly with a cloth, Thales showed, amber seemed to come alive, causing light objects—like feathers, straw, or leaves—to fly toward it, cling, and then gently detach and float away. Amber was similar to a magnet in its qualities, yet it was not a lodestone. As a youth, Thales of Miletus had studied in the sacred Egyptian cities of Memphis and Thebes. Perhaps it was there, under the burning sun, that this earliest of Greek philosophers first learned from the priests about the prized amber, with its seeming possession of a soul.[5]

Thales, it appears, believed amber an animate thing, something with soul.[6]

The Greek word for amber, elektron, ultimately through Latin, electrum, gave rise to the English words, electrical and electric — words used to refer to the amber phenomenon before the publication of William Gilbert's landmark work, De magnete, in 1600, describing the results of the first systematic experimental studies of magnetic and electrical phenomena in Western science.[7] [8]

The word, charge, used in its electrical sense, was first used by Benjamin Franklin, in 1747, as a verb, and subsequently by him as adjective and noun:

Our spheres are fixed on iron axes, which is passed through them. At one and of the axis there is a small handle, with which you turn the sphere like a common grindstone. This we find very commodious, as the machine takes up little room, is portable, and may be enclosed in a tight box, when not in use. 'Tis true, the sphere does not turn so swift as when the great wheel is used, but swiftness we think of little importance, since a few turns will charge the phial, etc., sufficiently. [italics added] [9]

Presumably, Franklin, who, in his many writings, frequently used the word, charge, and its variant forms (charging, charged, etc.), in its non-electrical sense, had in mind the word's sense of 'loading' or 'filling' something:

charge - ORIGIN: Middle English (in the general senses ‘to load’ and ‘a load’): from Old French charger (verb), charge (noun), from late Latin carricare, carcare ‘to load,’ from Latin carrus ‘wheeled vehicle.’...Examples: load or fill (a container, gun, etc.) to the full or proper extent: will you see to it that your glasses are charged? | fill or pervade (something) with a quality or emotion: the air was charged with menace.[10]

References

  1. Gibilisco S. (2005) Electricity Demystified. New York: McGraw-Hill. | Stan Gibilisco is an electronics engineer and mathematician, author of numerous technical books on electronics and mathematics.
  2. Elert G. (1998-2010) Electric Charge: Summary. The Physics Hypertextbook.
  3. Elert G. (1998-2010) Electric Charge. The Physics Hypertextbook.
  4. 4.0 4.1 Houston EJ. (1905) Electricity in every-day life. New York: P. F. Collier & Son, 1905. | Title link: Google Book Full-Text Volume 1 of 3.
    • That little piece of amber rubbed by Thales, some 2,500 years ago, appeared then to be very insignificant. Had the world but known, it was fraught with vast possibilities; for, in point of fact, Thales had unconsciously rediscovered Aladdin's Wonderful Lamp. As he rubbed, the Genie of electricity appeared, and demanded, "What wouldst thou have? I am ready to obey thee as the slave of the lamp, I and the other slaves of the lamp." But the question remained unanswered. Neither Thales nor the witnesses of his experiment made any request nor asked its genii to aid them. They had ears, but they heard not, and so the genie disappeared, with all that he was both willing and able to do left undone.
  5. 5.0 5.1 Jonnes J. (2004) Empires of Light: Edison, Tesla, Westinghouse, and the Race to Electrify the World. Random House Digital, Inc. ISBN 0375758844. | Title link: a Google Books extract.
  6. Barnes J. (1982) The Presocratic Philosophers'. Psychology Press. ISBN 978041505079. | Title link: Google Book extract.
  7. Electric. Webster's Third New International Dictionary, Unabridged. Merriam-Webster, 2002.
  8. Gilbert W. (1600, 1958) De magnete. Republication of the first English translation, from Gilbert's original in Latin, by P. Fleury Mottelay, in 1893. Courier Dover Publications. ISBN 9780486267616. | Google Books extract.
  9. Franklin B. (1769) Experiments And Observations On Electricity, Made At Philadelphia in America: To which are added, Letters and Papers On Philosophical Subjects. David Henry, publisher. | Google Books Full-Text.
    • See pages 311 for Franklin's 1747 letter to Peter Collinson, with Franklin's first use of 'charge'.
  10. charge v.. New Oxford American Dictionary. Edited by Angus Stevenson and Christine A. Lindberg. Oxford University Press, 2010. Oxford Reference Online. Oxford University Press. Accessed. 3 July 2011.



Opgen

Pioneer optogeneticist, Karl Deisseroth, defines optogenetics:

Optogenetics[1] is the combination of genetic and optical methods to achieve gain or loss of function of well-defined events in specific cells of living tissue.[2][Note 1]

Notes

  1. Deisseroth cites a well-illustrated review article in Scientific American magazine.

References

  1. Deisseroth K. (2010) Controlling the brain with light. Scientific American 303(5):48-55. PMID 21033283. | Extended/expanded version of article.
  2. Deisseroth K. (2011) Optogenetics. Nature Methods 8(1):26-29. PMID 21191368 | Special Feature: Method of the Year. Commentary.


stuff

Related links

Related links:

Optogenetics Resource Center

http://www.stanford.edu/group/dlab/optogenetics/index.html

Minimally Invasive Brain Stimulation

http://www.nature.com/nature/journal/v466/n7310_supp/box/466S15a_BX2.html

Optogenetics News

Ideas & Opinions | The Light Fantastic | by Robert Langreth |07.01.10, 10:20 AM EDT | Forbes Magazine dated July 19, 2010 This doctor reverse-engineers the mind with blue lasers and green algae.

http://www.stanford.edu/group/dlab/news.html

http://www.hfsp.org/PDF_Files/Press%20release%20-%20Nakasone%20Award%202010%20to%20Karl%20Deisseroth_final.pdf

Lectures on Microbial Opsin Optogenetics

http://www.stanford.edu/group/dlab/karlsfntalk.html http://www.youtube.com/watch?v=C8bPbHuOZXg

Test

text[1] [Note 1]

Notes

  1. Historian John F. Fulton quotes Vesalius as exclaiming:

    I acknowledge no authority save the witness of mine own eyes—I must have the liberty to compare the dicta of Galen with the observed facts of bodily structure.

refs

  1. Fulton JF. (1950) Vesalius Four Centuries Later. Logan Clendening Lectures on the History and Philosophy of Medicine, First Series: i Vesalius Four Centuries Later; ii Medicine in the Eighteenth Century. University of Kansas Press. | PDF.

Test-2

28.
UPDATE
What We Eat in America, NHANES 2007-2008
Mean Potassium Intakes. mg and mmoles per day


All Individuals, 2 and over

15% reporting potassium supplement

Sample Size, 8421

Food K, 2510 mg (SE 46.1) [64 mmoles]

Supplement K, 14 mg (SE 1.5) [<1 mmole]

Food + Supplement K, 2524 (SE 47.1) [65 mmoles]

Food + Supplement K, % of IOM recommendation, 50%


Males, 20 and over

21% reporting potassium supplement

Sample Size, 2662

Food K, 3026 mg (SE 50.4) [77 mmoles]

Supplement K, 22 (SE 1.8) [~1 mmole]

Food + Supplement K, 3048 (SE 51.2) [78 mmoles]

Food + Supplement K, % of IOM recommendation, 65%


Females, 20 and over

17% reporting potassium supplement

Sample Size, 2670

Food K, 2282 mg (SE 50.6) [58 mmoles]

Supplement K, 16 (SE 2.4) [<1 mmole]

—NHANES 2007-2008[1]


refs


Test3

Potassium Intake
What We Eat in America
2005-2006 and 2007-2008
Years
Gender
Potassium
mmol/day
%
Of
Recom-
mended
2005-2006
Men
81
68
2005-2006
Women
61
50
 
 
 
 
2007-2008
Men
78
65
2007-2008
Women
58
50
Recommended “Adequate Intake”, 120 mmol/day, identical for men and women, and therefore not adjusted for differences in body size or lean body mass between men and women.
Because the Food and Nutrition Board indicated that eating ordinary foods imposed no danger of consuming excess potassium except in certain potassium non-tolerant conditions, most Americans could likely achieve “adequate intakes” or more by doubling their potassium intake.

Holding References Various

[1]

Citations

  1. Cunningham A. (1997) The Anatomical Renaissance: The Resurrection of the Anatomical Projects of the Ancients. London: Scolar Press. ISBN 1859283381.

synbio

Somewhat more broadly, the American Chemical Society’s journal, ACS Synthetic Biology, states:

The journal is particularly interested in studies on the design and synthesis of new genetic circuits and gene products; computational methods in the design of systems; and integrative applied approaches to understanding disease and metabolism.

It lists the following topics as appropriate for a journal on synthetic biology:

Design and optimization of genetic systems
Genetic circuit design and their principles for their organization into programs
Computational methods to aid the design of genetic systems
Experimental methods to quantify genetic parts, circuits, and metabolic fluxes
Genetic parts libraries: their creation, analysis, and ontological representation
Protein engineering including computational design
Metabolic engineering and cellular manufacturing, including biomass conversion
Natural product access, engineering, and production
Creative and innovative applications of cellular programming
Medical applications, tissue engineering, and the programming of therapeutic cells
Minimal cell design and construction
Genomics and genome replacement strategies
Viral engineering
Automated and robotic assembly platforms for synthetic biology
DNA synthesis methodologies
Metagenomics and synthetic metagenomic analysis
Bioinformatics applied to gene discovery, chemoinformatics, and pathway construction
Gene optimization
Methods for genome-scale measurements of transcription and metabolomics
Systems biology and methods to integrate multiple data sources
in vitro and cell-free synthetic biology and molecular programming
Nucleic acid engineering

XLH

abc[1] def[2] ghi[3]

References

  1. Carpenter TO, Imel EA, Holm IA, Jan de Beur SM, Insogna KL. (2011) A clinician's guide to X-linked hypophosphatemia. J Bone Miner Res 26:1381-8.
    ↑ We briefly review the clinical and pathophysiologic features of the disorder and offer this guide in response to the conference recommendation, “Advances in Rare Bone Diseases Scientific Conference” NIH in October 2008, based on our collective accumulated experience in the management of this complex disorder.
  2. Carpenter TO, Insogna KL, Zhang JH et al. (2010) Circulating levels of soluble klotho and FGF23 in X-linked hypophosphatemia: circadian variance, effects of treatment, and relationship to parathyroid status. J Clin Endocrinol Metab 95:E352-E357.
    ↑ Serum klotho declines with age and demonstrates circadian variation but is normal in XLH. Serum FGF23 is similar in children and adults, is elevated in XLH, further increases with therapy, and demonstrates no diurnal variation. The direct relationship between FGF23 and PTH in subjects with XLH suggests that FGF23 regulation of PTH secretion is aberrant in this disorder.
  3. Imel EA, DiMeglio LA, Hui SL, Carpenter TO, Econs MJ. (2010) Treatment of X-linked hypophosphatemia with calcitriol and phosphate increases circulating fibroblast growth factor 23 concentrations. J Clin Endocrinol Metab 95:1846-50.
    ↑ Treating XLH with phosphate and calcitriol was associated with concurrent increases in circulating FGF23 concentrations, which may diminish therapeutic effect or contribute to complications of therapy. Because it is unknown whether the degree of FGF23 elevation correlates with disease severity in XLH, further study is needed to determine whether adjusting therapy to minimize effects on FGF23 concentration is warranted.


Timeline drawing test

(CC) Diagram: Anthony Sebastian
Add image caption here.

For lede Evolutionary linguistics

Some of the core questions in evolutionary linguistics are stated on the website of the linguistics department of the University of California, Santa Barbara:

Since spoken language does not leave any fossil record, the study of the origin and evolution of language is necessarily inferential on the basis of cross-disciplinary understanding of linguistics, neuroscience, paleoanthropology, molecular genetics, and animal cognition/communication. Of particular significance are those hominid behaviors that cannot take place without linguistic communication. A surprising issue that rises from this cross-disciplinary research is the nature of language.

  • In the continuum of the evolutionary development of human cognition and behavior adduced from the paleoanthropological records, when did hominid communication qualify as “language”?

0*Would the emergence of symbolic signals mark the beginning of language?

  • Was the appearance of the first symbolic signal among hominids the watershed event that led instantly to a cascade of new symbolic communicative signals within a few generations, or was the increase of symbolic signals a gradual process on an evolutionary time scale in accordance with the evolution of cognition?
  • Is there a “critical mass” of symbolic communicative signals that is necessary to trigger the development of grammar?
  • Did grammar emerge gradually on an evolutionary scale of time, contrary to the fast-paced emergence of grammar in pidginization and creolization?

[1]

There are many others, as will become apparent in this article.


refs

CS

Philosophers of mind, and all those scholars of myriad disciplines who have given serious inquiry into the nature of mind, have not agreed upon a definition of conscious experience, or ‘consciousness’, the term commonly used to refer to conscious experience. To quote a leading philosopher of mind, David Chalmers:

There is nothing that we know more intimately than conscious experience, but there is nothing that is harder to explain. [1]

Nicholas Humphrey, another leading philosopher of mind, elaborates:

The hard problem is to explain how an entity made entirely of physical matter—such as a human being—can experience conscious feelings. The problem is hard because such feelings appear to us, who are the subjects of them, to have properties that could not possibly be conjured out of matter alone.[2]

Philosopher of mind, David Rosenthal, gives the following definition(s):

The term 'consciousnes' is used in several ways: to describe a person or other creature as being awake and sentient, to describe a person or other creature as being 'aware of' something, and to refer to a property of mental states, such as perceiving, feeling, and thinking, that distinguishes those states from unconscious mental states.[3]

Philosopher of mind, Bernard Baars, asks us to consider this:

Our standard behavioral index for consciousness is the ability people have to report their experiences, often in ways that can be checked for accuracy.…... Under well-defined condition, such reports are exquisitely sensitive.… Conscious processes can be operationally defined as events that: (1) can be reported and acted upon, (2) with verifiable accuracy, (3) under optimal reporting conditions, (4) and which are reported as conscious.[4]


Holding in-line citations

Rosenthal 2010[3]

References cited

  1. Chalmers DJ. (1995) Facing Up to the Problem of Consciousness. Journal of Consciousness Studies 2(3):200-219. | Download full-text PDF.
  2. Humphrey N. (2011) Soul Dust: The Magic of Consciousness. Princeton University Press. Kindle Edition. | Google Books preview.
  3. 3.0 3.1 Rosenthal DM. (2010) Concepts and Definitions of Consciousness. In: Encyclopedia of Consciousness. Editor: William P. Banks. Focal Press. ISBN 9780123738738. | Google Books preview (Encyclopedia). | Google Books preview (Rosenthal chapter). | Download full-text (Rosenthal, second proof).
  4. Barnard J. Baars. Introduction: Treating Consciousness as a Variable: The Fading Taboo. Chapter 1. In: Essential Sources in the Scientific Study of Consciousness. Editors: Bernard J. Baars, William P. Banks, James B. Newman. MIT Press. ISBN 978026252308. | Google Books preview.