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{{Image|Reaction path.PNG|right|400px|A typical reaction path. In this example, energy is released. See Bergmann ''et al.''<ref name=Bergmann>
A '''chemical reaction''' is a process that transforms one set of [[Chemistry|chemical]] substances to another. The set of substances at the start of process are called '''''reactants''''' and the set present at the end of the process are called '''''products'''''. The study of chemical reactions is part of the field of [[science]] called [[chemistry]].
{{cite book|title=Constituents of Matter: Atoms, Molecules, Nuclei, and Particles |author=Nikolaus Risch |chapter=Molecules - bonds and reactions|editor=L. Bergmann ''et al.''|isbn=0-8493-1202-7|year=2002|publisher=CRC Press|url=http://books.google.com/?id=mGj1y1WYflMC&printsec=frontcover#PPA374,M1}}</ref>.}}
A '''chemical reaction''' is a process that transforms one set of [[Chemistry|chemical]] substances to another. The study of chemical reactions is part of the field of [[science]] called [[chemistry]].<ref name=Explained>[http://www.chemistryexplained.com/Ce-Co/Chemical-Reactions.html Chemistry Explained] Chemistry Encyclopedia</ref>


Chemical reactions can result in [[molecule]]s attaching to each other to form larger molecules, molecules breaking apart to form two or more smaller molecules, or rearrangement of [[atom]]s within or across molecules. Chemical reactions usually involve the making or breaking of [[chemical bond]]s.
Chemical reactions can result in [[molecule]]s attaching to each other to form larger molecules, molecules breaking apart to form two or more smaller molecules, or rearrangement of [[atom]]s within or across molecules. Chemical reactions usually involve the making or breaking of [[chemical bond]]s, and in some types of reaction may involve production of electrically charged end products. Reactions can occur in various environments: gases, liquids, solids, or combinations of same: for example, at interfaces.


Chemical reactions can be either spontaneous<ref name=Rosengarten>[http://www.youtube.com/watch?v=m1nKEz2DPC0 Chemistry Tutorials: Entropy, Enthalpy and Spontaneous Reactions]</ref> and require no input of [[energy]], or non-spontaneous<ref name=Rosengarten/> which often require the input of some type of energy such as [[heat]], [[light]] or [[electricity]]. Classically, chemical reactions are strictly transformations that involve the movement of [[electron]] in the forming and breaking of [[chemical bond]]s. A more general concept of a chemical reaction would include [[nuclear reactions]] and [[Elementary particle|elementary particle reactions]].
As shown in the adjacent figure for a general case, the participating '''reactants''' typically must surmount a threshold energy or ''activation energy'' to initiate the reaction, and '''intermediates''' exist briefly before the final '''products''' are formed. Changes in [[Chemical bond|bonding]] of a single occurrence of the transformation is not all that is involved in the energy depicted, which is intended to show the evolution of an entire soup of reactants, intermediates and products. This evolution typically involves generation of heat, physical motion and mixing of all the participants, and the chemical reactions. In the figure, the activation energy on the left indicates the change in all these factors needed to surmount the activation threshold and the energy output on the right indicates the change in these factors when the reaction is complete, being the difference between the starting system with only the reactants themselves and the ending system consisting only of the final products. This overall change in energy may be made to do useful work, or simply be dissipated as heat.<ref name= Moore>
 
For a qualitative discussion see, for example, {{cite book |title=Principles of Chemistry: The Molecular Science |author=John W. Moore, Conrad L. Stanitski, Peter C. Jurs |pages=pp. 633 ''ff'' |chapter=Coupling reactant-favored processes with product-favored processes |isbn=0495390798 |year=2009 |publisher=Cengage Learning|url=http://books.google.com/books?id=ZOm8L9oCwLMC&pg=PA633}} and {{cite book |title=Modern physical organic chemistry |author=Eric V. Anslyn, Dennis A. Dougherty |pages=pp. 68 ''ff'' |chapter=§2.1.2: Types of energy |url=http://books.google.com/books?id=gY-Sxijk_tMC&pg=PA68 |isbn=1891389319 |year=2006 |publisher=University Science Books}}
 
</ref>
 
Chemical reactions can be either spontaneous<ref name=Rosengarten>
 
{{cite web |title= Chemistry tutorial 9.03: Entropy, enthalpy and spontaneous reactions |url=http://www.youtube.com/watch?v=m1nKEz2DPC0 |author=Mark Rosengarten |work=Regents chemistry tutorials on YouTube |year=2009 |accessdate=2011-04-06}}
 
</ref> and require no input of [[energy]], or non-spontaneous<ref name=Rosengarten/> which often require the input of some type of energy such as [[heat]], [[light]] or [[electricity]]. Classically, chemical reactions are strictly transformations that involve the movement of [[electron]]s during the forming and breaking of [[chemical bond]]s. A more general concept of a chemical reaction would include [[nuclear reactions]] and [[Elementary particle|elementary particle reactions]].


==Energy changes in reactions==
==Energy changes in reactions==
 
{{Image|ExoEndo Reax.png|right|400px|Energy level diagrams of exothermic and endothermic reactions.<ref>[http://www2.chemistry.msu.edu/faculty/reusch/VirtTxtJml/react2.htm Examples of Organic Reactions] ''Virtual Textbook of Organic Chemistry'', William Reusch, Emeritus Professor, Department of Chemistry, [[Michigan State University]]. Scroll down to section on "Activation Energy".</ref><ref>{{cite book|author=Frederick A. Bettelheim, William H. Brown, Mary K. Campbell and Shawn O. Farrell|title= Introduction to General, Organic and Biochemistry|edition=|publisher=Brooks/Cole, Cengage Learning|pages=pp.215-216|date=2009|id=ISBN 0-495-39112-3}} Partally available [http://books.google.com/books?id=mM-Ulksh9PAC&printsec=frontcover&dq=inauthor:bettelheim&hl=en&ei=buucTcjcOorYgQeSn7WBw&sa=X&oi=book_result&ct=result&resnum=3&ved=0CDcQ6AEwAg#v=onepage&q=Activation&f=false here] at Google Books.</ref><ref>{{cite book|author=Paul Collison, David Kirkby and Averil Macdonald |title=Nelson Modular Science, Book 2 |url=http://books.google.com/books?id=gnEr8IMGM_UC&pg=PT154 |pages=pp. 151 ''ff'' |chapter=§10.08: Energy changes in chemical reactions  |edition=|publisher=Nelson Thornes Ltd.|year=2003 |isbn=0748767797}}</ref>}}
{{Image|ExoEndo Reax.png|right|400px|Energy level diagrams of exothermic and endothermic reactions<ref>{{cite book|author=Paul Collison, David Kirby and Averil Macdonald|title=Nelson Modular Science, Volume 2|edition=|publisher=Nelson Thorne Ltd.|year=2002|id=ISBN 0-7487-6247-7}}</ref>}}


In terms of the [[energy]] changes that take place during chemical reactions, a reaction may be either '''''exothermic''''' or '''''endothermic''''' ... terms which were first coined by the [[France|French]] chemist [[Marcellin Berthelot]] (1827 − 1907). The meaning of those terms and the difference between them are discussed below and illustrated in the adjacent diagram of the energy profiles for exothermic and endothermic reactions.
In terms of the [[energy]] changes that take place during chemical reactions, a reaction may be either '''''exothermic''''' or '''''endothermic''''' ... terms which were first coined by the [[France|French]] chemist [[Marcellin Berthelot]] (1827 − 1907). The meaning of those terms and the difference between them are discussed below and illustrated in the adjacent diagram of the energy profiles for exothermic and endothermic reactions.


===Exothermic reactions===
===Exothermic reactions===
 
Exothermic chemical reactions release energy. The released energy may be in the form of heat, light (for example, flame), electricity (for example, [[battery]] discharge),  [[sound]] and [[shock wave]]s (for example, [[explosion]]) &hellip; either singly or in combinations.  
Exothermic chemical reactions release energy. The released energy may be in the form of heat, light (e.g., flame), electricity (e.g., [[battery]] discharge),  [[sound]] and [[shock wave]]s (e.g., [[explosion]]) .... either singly or in combinations.  


A few examples of exothermic reactions are:
A few examples of exothermic reactions are:
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===Endothermic reactions===
===Endothermic reactions===
Endothermic chemical reactions absorb energy. The energy absorbed may be in various forms just as is the case with exothermic reactions:
Endothermic chemical reactions absorb energy. The energy absorbed may be in various forms just as is the case with exothermic reactions:


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== Reaction types ==
== Reaction types ==
 
The common kinds of classical chemical reactions include:<ref>In the following [[chemical equation]]s, (aq) indicates an aqueous solution, (g) indicates a gas and (s) indicates a solid. Superscripts with a positive sign (+)  indicate an [[Ion|cation]] and superscripts with a negative sign (−) indicate an [[Ion|anion]].</ref><ref>{{cite book|author=H. Stephen Stoker|title=General, Organic, and Biological Chemistry|edition=5th Edition|publisher=Brooks/Cole: Cengage Learning|year=2009 |isbn= 0547152817 |url=http://books.google.com/books?id=Yig6eLv_O4MC&pg=PA223 |pages=pp. 223 ''ff'' |chapter=Chapter 9: Chemical reactions }}</ref><ref name=Cracolice>{{cite book|author=Mark S. Cracolice and Edward I. Peters| title=Introductory Chemistry: An Active Learning Approach|edition=4th Edition|publisher=Brooks/Cole: Cengage Learning|year=2009 |id= ISBN 0-495-55847-8 |url=http://books.google.com/books?id=1l79dsiyv0gC&pg=PT77 |pages=pp. 77 ''ff'' |chapter=§2.8: Characteristics of a chemical change}}</ref>
The common kinds of classical chemical reactions include:<ref>In the following [[chemical equation]]s, (aq) indicates an aqueous solution, (g) indicates a gas and (s) indicates a solid. Superscripts with a positive sign (+)  indicate an [[Ion|cation]] and superscripts with a negative sign (−) indicate an [[Ion|anion]].</ref><ref>{{cite book|author=H. Stephen Stoker|title=General, Organic, and Biological Chemistry|edition=4th Edition|publisher=Brooks Cole|year=2006|ISBN=0-618-60606-8}}</ref>


*[[Isomerization]], in which a [[chemical compound]] undergoes a structural rearrangement without any change in its net atomic composition (see [[stereoisomerism]])
*[[Isomerization]], in which a [[chemical compound]] undergoes a structural rearrangement without any change in its net atomic composition (see [[stereoisomerism]])
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==References==
==References==
<references/>
{{reflist}}[[Category:Suggestion Bot Tag]]

Latest revision as of 11:00, 27 July 2024

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(PD) Image: John R. Brews
A typical reaction path. In this example, energy is released. See Bergmann et al.[1].

A chemical reaction is a process that transforms one set of chemical substances to another. The study of chemical reactions is part of the field of science called chemistry.[2]

Chemical reactions can result in molecules attaching to each other to form larger molecules, molecules breaking apart to form two or more smaller molecules, or rearrangement of atoms within or across molecules. Chemical reactions usually involve the making or breaking of chemical bonds, and in some types of reaction may involve production of electrically charged end products. Reactions can occur in various environments: gases, liquids, solids, or combinations of same: for example, at interfaces.

As shown in the adjacent figure for a general case, the participating reactants typically must surmount a threshold energy or activation energy to initiate the reaction, and intermediates exist briefly before the final products are formed. Changes in bonding of a single occurrence of the transformation is not all that is involved in the energy depicted, which is intended to show the evolution of an entire soup of reactants, intermediates and products. This evolution typically involves generation of heat, physical motion and mixing of all the participants, and the chemical reactions. In the figure, the activation energy on the left indicates the change in all these factors needed to surmount the activation threshold and the energy output on the right indicates the change in these factors when the reaction is complete, being the difference between the starting system with only the reactants themselves and the ending system consisting only of the final products. This overall change in energy may be made to do useful work, or simply be dissipated as heat.[3]

Chemical reactions can be either spontaneous[4] and require no input of energy, or non-spontaneous[4] which often require the input of some type of energy such as heat, light or electricity. Classically, chemical reactions are strictly transformations that involve the movement of electrons during the forming and breaking of chemical bonds. A more general concept of a chemical reaction would include nuclear reactions and elementary particle reactions.

Energy changes in reactions

(PD) Diagram: Milton Beychok
Energy level diagrams of exothermic and endothermic reactions.[5][6][7]

In terms of the energy changes that take place during chemical reactions, a reaction may be either exothermic or endothermic ... terms which were first coined by the French chemist Marcellin Berthelot (1827 − 1907). The meaning of those terms and the difference between them are discussed below and illustrated in the adjacent diagram of the energy profiles for exothermic and endothermic reactions.

Exothermic reactions

Exothermic chemical reactions release energy. The released energy may be in the form of heat, light (for example, flame), electricity (for example, battery discharge), sound and shock waves (for example, explosion) … either singly or in combinations.

A few examples of exothermic reactions are:

Endothermic reactions

Endothermic chemical reactions absorb energy. The energy absorbed may be in various forms just as is the case with exothermic reactions:

A few examples of endothermic reactions are:

Reaction types

The common kinds of classical chemical reactions include:[8][9][10]

N2 + 3 H2 → 2 NH3
2 H2O → 2 H2 + O2
2 Na(s) + 2 HCl(aq) → 2 NaCl(aq) + H2(g)
NaCl(aq) + AgNO3(aq) → NaNO3(aq) + AgCl(s)
  • Acid-base reactions, broadly characterized as reactions between an acid and a base, can have different definitions depending on the acid-base concept employed. Some of the most common are:
    • Arrhenius definition: Acids dissociate in water releasing H3O+ ions; bases dissociate in water releasing OH ions.
    • Brønsted-Lowry definition: Acids are proton (H+) donors; bases are proton acceptors. Includes the Arrhenius definition.
    • Lewis definition: Acids are electron-pair acceptors; bases are electron-pair donors. Includes the Brønsted-Lowry definition.
  • Redox reactions, in which changes in the oxidation numbers of atoms in the involved species occur. Those reactions can often be interpreted as transferences of electrons between different molecular sites or species. An example of a redox reaction is:
2 S2O32−(aq) + I2(aq) → S4O62−(aq) + 2 I(aq)
In which iodine (I2) is reduced to the iodine anion (I) and the thiosulfate anion (S2O32−) is oxidized to the tetrathionate anion (S4O62−).
  • Combustion, a kind of redox reaction in which any combustible substance combines with an oxidizing element, usually oxygen, to generate heat and form oxidized products.
CH4 + 2 O2CO2 + 2 H2O
  • Disproportionation with one reactant forming two distinct products varying in oxidation state.
2 Sn2+Sn + Sn4+

References

  1. Nikolaus Risch (2002). “Molecules - bonds and reactions”, L. Bergmann et al.: Constituents of Matter: Atoms, Molecules, Nuclei, and Particles. CRC Press. ISBN 0-8493-1202-7. 
  2. Chemistry Explained Chemistry Encyclopedia
  3. For a qualitative discussion see, for example, John W. Moore, Conrad L. Stanitski, Peter C. Jurs (2009). “Coupling reactant-favored processes with product-favored processes”, Principles of Chemistry: The Molecular Science. Cengage Learning, pp. 633 ff. ISBN 0495390798.  and Eric V. Anslyn, Dennis A. Dougherty (2006). “§2.1.2: Types of energy”, Modern physical organic chemistry. University Science Books, pp. 68 ff. ISBN 1891389319. 
  4. 4.0 4.1 Mark Rosengarten (2009). Chemistry tutorial 9.03: Entropy, enthalpy and spontaneous reactions. Regents chemistry tutorials on YouTube. Retrieved on 2011-04-06.
  5. Examples of Organic Reactions Virtual Textbook of Organic Chemistry, William Reusch, Emeritus Professor, Department of Chemistry, Michigan State University. Scroll down to section on "Activation Energy".
  6. Frederick A. Bettelheim, William H. Brown, Mary K. Campbell and Shawn O. Farrell (2009). Introduction to General, Organic and Biochemistry. Brooks/Cole, Cengage Learning, pp.215-216. ISBN 0-495-39112-3.  Partally available here at Google Books.
  7. Paul Collison, David Kirkby and Averil Macdonald (2003). “§10.08: Energy changes in chemical reactions”, Nelson Modular Science, Book 2. Nelson Thornes Ltd., pp. 151 ff. ISBN 0748767797. 
  8. In the following chemical equations, (aq) indicates an aqueous solution, (g) indicates a gas and (s) indicates a solid. Superscripts with a positive sign (+) indicate an cation and superscripts with a negative sign (−) indicate an anion.
  9. H. Stephen Stoker (2009). “Chapter 9: Chemical reactions”, General, Organic, and Biological Chemistry, 5th Edition. Brooks/Cole: Cengage Learning, pp. 223 ff. ISBN 0547152817. 
  10. Mark S. Cracolice and Edward I. Peters (2009). “§2.8: Characteristics of a chemical change”, Introductory Chemistry: An Active Learning Approach, 4th Edition. Brooks/Cole: Cengage Learning, pp. 77 ff. ISBN 0-495-55847-8.