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{{Short description|Chemistry based on quantum physics}}{{Cleanup|reason=weak information content|date=May 2023}}
{{Short description|Chemistry based on quantum physics}}{{Cleanup|reason=weak information content|date=May 2023}}


'''Quantum chemistry''', also called '''molecular quantum mechanics''', is a branch of [[physical chemistry]] focused on the application of [[quantum mechanics]] to chemical systems, particularly towards the quantum-mechanical calculation of electronic contributions to physical and chemical properties of [[Molecule|molecules]], [[Material|materials]], and solutions at the atomic level.<ref>{{Cite book |last=McQuarrie |first=Donald A. |title=Quantum Chemistry |publisher=University Science Books |year=2007 |isbn=978-1891389504 |edition=2nd}}</ref> These calculations include systematically applied approximations intended to make calculations computationally feasible while still capturing as much information about important contributions to the computed [[Wave function|wave functions]] as well as to observable properties such as structures, spectra, and thermodynamic properties. Quantum chemistry is also concerned with the computation of quantum effects on [[molecular dynamics]] and [[chemical kinetics]].
'''Quantum chemistry''', also called '''molecular quantum mechanics''', is a branch of [[physical chemistry]] focused on the application of [[quantum mechanics]] to chemical systems, particularly towards the quantum-mechanical calculation of electronic contributions to physical and chemical properties of [[Molecule|molecules]], [[Material|materials]], and solutions at the atomic level.<ref>{{Cite book |last=McQuarrie |first=Donald A. |title=Quantum Chemistry |publisher=University Science Books |year=2007 |isbn=978-1891389504 |edition=2nd}}</ref> These calculations include systematically applied approximations intended to make calculations computationally feasible while still capturing as much information about important contributions to the computed [[Wave function|wave functions]] as well as to observable properties such as structures, spectra, and [[Thermodynamics|thermodynamic]] properties. Quantum chemistry is also concerned with the computation of quantum effects on [[molecular dynamics]] and [[chemical kinetics]].


Chemists rely heavily on [[spectroscopy]] through which information regarding the [[Quantization (physics)|quantization]] of energy on a molecular scale can be obtained. Common methods are [[infra-red (IR) spectroscopy]], [[nuclear magnetic resonance (NMR) spectroscopy]], and [[scanning probe microscopy]]. Quantum chemistry may be applied to the prediction and verification of spectroscopic data as well as other experimental data.
Chemists rely heavily on [[spectroscopy]] through which information regarding the [[Quantization (physics)|quantization]] of energy on a molecular scale can be obtained. Common methods are [[infra-red (IR) spectroscopy]], [[nuclear magnetic resonance (NMR) spectroscopy]], and [[scanning probe microscopy]]. Quantum chemistry may be applied to the prediction and verification of spectroscopic data as well as other experimental data.


Many quantum chemistry studies are focused on the electronic [[ground state]] and [[excited state|excited states]] of individual atoms and molecules as well as the study of reaction pathways and [[transition state]]s that occur during [[chemical reaction]]s. Spectroscopic properties may also be predicted. Typically, such studies assume the electronic wave function is adiabatically parameterized by the nuclear positions (i.e., the [[Born–Oppenheimer approximation]]). A wide variety of approaches are used, including [[Semi-empirical quantum chemistry method|semi-empirical]] methods, [[density functional theory]], [[Hartree-Fock]] calculations, quantum [[Monte Carlo method|Monte Carlo]] methods, and [[coupled cluster]] methods.
Many quantum chemistry studies are focused on the electronic [[ground state]] and [[excited state|excited states]] of individual atoms and molecules as well as the study of reaction pathways and [[transition state]]s that occur during [[chemical reaction]]s. Spectroscopic properties may also be predicted. Typically, such studies assume the electronic wave function is adiabatically parameterized by the nuclear positions (i.e., the [[Born–Oppenheimer approximation]]). A wide variety of approaches are used, including [[semi-empirical quantum chemistry method|semi-empirical]] methods, [[density functional theory]], [[Hartree–Fock method|Hartree–Fock]] calculations, quantum [[Monte Carlo method|Monte Carlo]] methods, and [[coupled cluster]] methods.


Understanding [[electronic structure]] and [[molecular dynamics]] through the development of computational solutions to the [[Schrödinger equation]] is a central goal of quantum chemistry. Progress in the field depends on overcoming several challenges, including the need to increase the accuracy of the results for small molecular systems, and to also increase the size of large molecules that can be realistically subjected to computation, which is limited by scaling considerations — the computation time increases as a power of the number of atoms.
Understanding [[electronic structure]] and [[molecular dynamics]] through the development of computational solutions to the [[Schrödinger equation]] is a central goal of quantum chemistry. Progress in the field depends on overcoming several challenges, including the need to increase the accuracy of the results for small molecular systems, and to also increase the size of large molecules that can be realistically subjected to computation, which is limited by scaling considerations — the computation time increases as a power of the number of atoms.


==History==
==History==
Some view the birth of quantum chemistry as starting with the discovery of the [[Schrödinger equation]] and its application to the hydrogen atom. However, a 1927 article of [[Walter Heitler]] (1904–1981) and [[Fritz London]] is often recognized as the first milestone in the history of quantum chemistry.<ref>{{Cite journal |last=Heitler |first=W. |last2=London |first2=F. |date=1927 |title=Wechselwirkung neutraler Atome und homopolare Bindung nach der Quantenmechanik |url=http://dx.doi.org/10.1007/BF01397394 |journal=Zeitschrift für Physik |volume=44 |pages=455-472}}</ref> This was the first application of quantum mechanics to the diatomic [[hydrogen molecule]], and thus to the phenomenon of the chemical bond.<ref>{{Cite book |last=Kołos |first=W. |url=https://doi.org/10.1007/978-94-009-0949-6_8 |title=Perspectives in Quantum Chemistry. Académie Internationale Des Sciences Moléculaires Quantiques/International Academy of Quantum Molecular Science |publisher=Springer |year=1989 |volume=6 |location=Dordrecht |chapter=The Origin, Development and Significance of the Heitler-London Approach}}</ref> However, prior to this a critical conceptual framework was provided by [[Gilbert N. Lewis]] in his 1916 paper ''The Atom and the Molecule'',<ref>{{Cite journal |last=Lewis |first=G.N. |title=The Atom and the Molecule |url=http://dx.doi.org/10.1021/ja02261a002 |journal=[[Journal of the American Chemical Society]] |volume=38 |pages=762-785}}</ref> wherein Lewis developed the first working model of [[Valence electron|valence electrons]]. Important contributions were also made by Yoshikatsu Sugiura<ref>{{Cite journal |last=Sugiura |first=Y. |date=1927 |title=Über die Eigenschaften des Wasserstoffmoleküls im Grundzustande |url=https://link.springer.com/article/10.1007/BF01329207 |journal=Zeitschrift für Physik |volume=45 |pages=484-492}}</ref><ref>{{Cite journal |last=Nakane |first=Michiyo |date=2019 |title=Yoshikatsu Sugiura's Contribution to the Development of Quantum Physics in Japan |url=https://onlinelibrary.wiley.com/doi/10.1002/bewi.201900007 |journal=Berichte zur Wissenschaftsgeschichte |volume=42 |pages=338}}</ref> and S.C. Wang.<ref>{{Cite journal |last=Wang |first=S. C. |date=1928-04-01 |title=The Problem of the Normal Hydrogen Molecule in the New Quantum Mechanics |url=https://link.aps.org/doi/10.1103/PhysRev.31.579 |journal=Physical Review |volume=31 |issue=4 |pages=579–586 |doi=10.1103/PhysRev.31.579}}</ref> A series of articles by [[Linus Pauling]], written throughout the 1930s, integrated the work of Heitler, London, Sugiura, Wang, Lewis, and [[John C. Slater]] on the concept of valence and its quantum-mechanical basis into a new theoretical framework.<ref>{{Cite journal |last=Pauling |first=Linus |date=April 6, 1931 |title=The nature of the chemical bond. Application of results obtained from the quantum mechanics and from a theory of paramagnetic susceptibility to the structure of molecules |url=http://scarc.library.oregonstate.edu/coll/pauling/bond/papers/1931p.3.html |journal=[[Journal of the American Chemical Society]] |volume=53 |pages=1367-1400 |via=Oregon State University Library}}</ref> Many chemists were introduced to the field of quantum chemistry by Pauling's 1939 text ''The Nature of the Chemical Bond and the Structure of Molecules and Crystals: An Introduction to Modern Structural Chemistry'', wherein he summarized this work (referred to widely now as [[valence bond theory]]) and explained quantum mechanics in a way which could be followed by chemists.<ref>{{Cite book |last=Pauling |first=Linus |title=The Nature of the Chemical Bond and the Structure of Molecules and Crystals: An Introduction to Modern Structural Chemistry |publisher=Cornell University Press |year=1939 |edition=1st}}</ref> The text soon became a standard text at many universities. <ref>{{Cite web |last=Norman |first=Jeremy |title=Pauling Publishes "The Nature of the Chemical Bond" |url=https://historyofinformation.com/detail.php?id=3956 |access-date=July 11, 2023 |website=History of Information}}</ref> In 1937, [[Hans Hellmann]] appears to have been the first to publish a book on quantum chemistry, in the Russian <ref>{{cite book|year=1937|last1=Хельман|first1=Г.|title=Квантовая Химия|publisher=Главная Редакция Технико-Теоретической Литературы, Moscow and Leningrad}}</ref> and German languages.<ref>{{cite book|year=1937|last1=Hellmann|first1=Hans|title=Einführung in die Quantenchemie|publisher= Deuticke, Leipzig und Wien}}</ref>
Some view the birth of quantum chemistry as starting with the discovery of the [[Schrödinger equation]] and its application to the hydrogen atom. However, a 1927 article of [[Walter Heitler]] (1904–1981) and [[Fritz London]] is often recognized as the first milestone in the history of quantum chemistry.<ref>{{Cite journal |last1=Heitler |first1=W. |last2=London |first2=F. |date=1927 |title=Wechselwirkung neutraler Atome und homopolare Bindung nach der Quantenmechanik |url=http://dx.doi.org/10.1007/BF01397394 |journal=Zeitschrift für Physik |volume=44 |issue=6–7 |pages=455–472|doi=10.1007/BF01397394 |bibcode=1927ZPhy...44..455H }}</ref> This was the first application of quantum mechanics to the diatomic [[hydrogen molecule]], and thus to the phenomenon of the chemical bond.<ref>{{Cite book |last=Kołos |first=W. |url=https://doi.org/10.1007/978-94-009-0949-6_8 |title=Perspectives in Quantum Chemistry. Académie Internationale Des Sciences Moléculaires Quantiques/International Academy of Quantum Molecular Science |publisher=Springer |year=1989 |volume=6 |location=Dordrecht |chapter=The Origin, Development and Significance of the Heitler-London Approach|pages=145–159 |doi=10.1007/978-94-009-0949-6_8 |isbn=978-94-010-6917-5 }}</ref> However, prior to this a critical conceptual framework was provided by [[Gilbert N. Lewis]] in his 1916 paper ''The Atom and the Molecule'',<ref>{{Cite journal |last=Lewis |first=G.N. |title=The Atom and the Molecule |url=http://dx.doi.org/10.1021/ja02261a002 |journal=[[Journal of the American Chemical Society]] |date=1916 |volume=38 |issue=4 |pages=762–785|doi=10.1021/ja02261a002 }}</ref> wherein Lewis developed the first working model of [[Valence electron|valence electrons]]. Important contributions were also made by Yoshikatsu Sugiura<ref>{{Cite journal |last=Sugiura |first=Y. |date=1927 |title=Über die Eigenschaften des Wasserstoffmoleküls im Grundzustande |url=https://link.springer.com/article/10.1007/BF01329207 |journal=Zeitschrift für Physik |volume=45 |issue=7–8 |pages=484–492|doi=10.1007/BF01329207 |bibcode=1927ZPhy...45..484S }}</ref><ref>{{Cite journal |last=Nakane |first=Michiyo |date=2019 |title=Yoshikatsu Sugiura's Contribution to the Development of Quantum Physics in Japan |url=https://onlinelibrary.wiley.com/doi/10.1002/bewi.201900007 |journal=Berichte zur Wissenschaftsgeschichte |volume=42 |issue=4 |pages=338–356|doi=10.1002/bewi.201900007 |pmid=31777981 }}</ref> and S.C. Wang.<ref>{{Cite journal |last=Wang |first=S. C. |date=1928-04-01 |title=The Problem of the Normal Hydrogen Molecule in the New Quantum Mechanics |url=https://link.aps.org/doi/10.1103/PhysRev.31.579 |journal=Physical Review |volume=31 |issue=4 |pages=579–586 |doi=10.1103/PhysRev.31.579|bibcode=1928PhRv...31..579W }}</ref> A series of articles by [[Linus Pauling]], written throughout the 1930s, integrated the work of Heitler, London, Sugiura, Wang, Lewis, and [[John C. Slater]] on the concept of valence and its quantum-mechanical basis into a new theoretical framework.<ref>{{Cite journal |last=Pauling |first=Linus |date=April 6, 1931 |title=The nature of the chemical bond. Application of results obtained from the quantum mechanics and from a theory of paramagnetic susceptibility to the structure of molecules |url=http://scarc.library.oregonstate.edu/coll/pauling/bond/papers/1931p.3.html |journal=[[Journal of the American Chemical Society]] |volume=53 |issue=4 |pages=1367–1400 |doi=10.1021/ja01355a027 |via=Oregon State University Library}}</ref> Many chemists were introduced to the field of quantum chemistry by Pauling's 1939 text ''The Nature of the Chemical Bond and the Structure of Molecules and Crystals: An Introduction to Modern Structural Chemistry'', wherein he summarized this work (referred to widely now as [[valence bond theory]]) and explained quantum mechanics in a way which could be followed by chemists.<ref>{{Cite book |last=Pauling |first=Linus |title=The Nature of the Chemical Bond and the Structure of Molecules and Crystals: An Introduction to Modern Structural Chemistry |publisher=Cornell University Press |year=1939 |edition=1st}}</ref> The text soon became a standard text at many universities. <ref>{{Cite web |last=Norman |first=Jeremy |title=Pauling Publishes "The Nature of the Chemical Bond" |url=https://historyofinformation.com/detail.php?id=3956 |access-date=July 11, 2023 |website=History of Information}}</ref> In 1937, [[Hans Hellmann]] appears to have been the first to publish a book on quantum chemistry, in the Russian <ref>{{cite book|year=1937|last1=Хельман|first1=Г.|title=Квантовая Химия|publisher=Главная Редакция Технико-Теоретической Литературы, Moscow and Leningrad}}</ref> and German languages.<ref>{{cite book|year=1937|last1=Hellmann|first1=Hans|title=Einführung in die Quantenchemie|publisher= Deuticke, Leipzig und Wien}}</ref>


In the years to follow, this theoretical basis slowly began to be applied to chemical structure, reactivity, and bonding. In addition to the investigators mentioned above, important progress and critical contributions were made in the early years of this field by [[Irving Langmuir]], [[Robert S. Mulliken]], [[Max Born]], [[J. Robert Oppenheimer]], [[Hans Hellmann]], [[Maria Goeppert Mayer]], [[Erich Hückel]], [[Douglas Hartree]], [[John Lennard-Jones]], and [[Vladimir Fock]].
In the years to follow, this theoretical basis slowly began to be applied to chemical structure, reactivity, and bonding. In addition to the investigators mentioned above, important progress and critical contributions were made in the early years of this field by [[Irving Langmuir]], [[Robert S. Mulliken]], [[Max Born]], [[J. Robert Oppenheimer]], [[Hans Hellmann]], [[Maria Goeppert Mayer]], [[Erich Hückel]], [[Douglas Hartree]], [[John Lennard-Jones]], and [[Vladimir Fock]].


== Electronic structure ==
== Electronic structure ==
The '''electronic structure''' of an atom or molecule is the [[quantum state]] of its electrons.<ref>{{cite book|last=Simons|first=Jack|title=An introduction to theoretical chemistry|year=2003|publisher=Cambridge University Press|location=Cambridge, UK|chapter=Chapter 6. Electronic Structures|isbn=0521823609|url=http://simons.hec.utah.edu/ITCSecondEdition/chapter6.pdf}}</ref> The first step in solving a quantum chemical problem is usually solving the [[Schrödinger equation]] (or [[Dirac equation]] in [[relativistic quantum chemistry]]) with the [[electronic molecular Hamiltonian]], usually making use of the Born–Oppenheimer (B–O) approximation. This is called determining the electronic structure of the molecule.<ref>{{Cite book |last=Martin |first=Richard M. |title=Electronic Structure: Basic Theory and Practical Methods |date=2008-10-27 |publisher=Cambridge University Press |isbn=978-0-521-53440-6 |location=Cambridge |language=English}}</ref> An exact solution for the non-relativistic Schrödinger equation can only be obtained for the hydrogen atom (though exact solutions for the bound state energies of the [[dihydrogen cation|hydrogen molecular ion]] within the B-O approximation have been identified in terms of the [[Lambert W function#Generalizations|generalized Lambert W function]]). Since all other atomic and molecular systems involve the motions of three or more "particles", their Schrödinger equations cannot be solved analytically and so approximate and/or computational solutions must be sought. The process of seeking computational solutions to these problems is part of the field known as [[computational chemistry]].
{{main|Electronic structure}}

The first step in solving a quantum chemical problem is usually solving the [[Schrödinger equation]] (or [[Dirac equation]] in [[relativistic quantum chemistry]]) with the [[electronic molecular Hamiltonian]], usually making use of the Born-Oppenheimer (B-O) approximation. This is called determining the electronic structure of the molecule.<ref>{{Cite book |last=Martin |first=Richard M. |title=Electronic Structure: Basic Theory and Practical Methods |date=2008-10-27 |publisher=Cambridge University Press |isbn=978-0-521-53440-6 |location=Cambridge |language=English}}</ref> An exact solution for the non-relativistic Schrödinger equation can only be obtained for the hydrogen atom (though exact solutions for the bound state energies of the [[Dihydrogen cation|hydrogen molecular ion]] within the B-O approximation have been identified in terms of the [[Lambert W function#Generalizations|generalized Lambert W function]]). Since all other atomic and molecular systems involve the motions of three or more "particles", their Schrödinger equations cannot be solved analytically and so approximate and/or computational solutions must be sought. The process of seeking computational solutions to these problems is part of the field known as [[computational chemistry]].


=== Valence bond theory ===
=== Valence bond theory ===
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As mentioned above, Heitler and London's method was extended by Slater and Pauling to become the valence-bond (VB)
As mentioned above, Heitler and London's method was extended by Slater and Pauling to become the valence-bond (VB)
method. In this method, attention is primarily devoted to the pairwise interactions between atoms, and this method therefore correlates closely with classical chemists' drawings of [[chemical bond|bonds]]. It focuses on how the atomic orbitals of an atom combine to give individual chemical bonds when a molecule is formed, incorporating the two key concepts of [[orbital hybridization]] and [[resonance (chemistry)|resonance]].<ref>{{Cite book |last=Shaik |first=S.S. |title=A Chemist's Guide to Valence Bond Theory |last2=Hiberty |first2=P.C. |publisher=Wiley-Interscience |year=2007 |isbn=978-0470037355}}</ref>
method. In this method, attention is primarily devoted to the pairwise interactions between atoms, and this method therefore correlates closely with classical chemists' drawings of [[chemical bond|bonds]]. It focuses on how the atomic orbitals of an atom combine to give individual chemical bonds when a molecule is formed, incorporating the two key concepts of [[orbital hybridization]] and [[resonance (chemistry)|resonance]].<ref>{{Cite book |last1=Shaik |first1=S.S. |title=A Chemist's Guide to Valence Bond Theory |last2=Hiberty |first2=P.C. |publisher=Wiley-Interscience |year=2007 |isbn=978-0470037355}}</ref>


=== Molecular orbital theory ===
=== Molecular orbital theory ===
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{{main|Molecular orbital theory}}
{{main|Molecular orbital theory}}


An alternative approach to valence bond theory was developed in 1929 by [[Friedrich Hund]] and [[Robert S. Mulliken]], in which [[electron]]s are described by mathematical functions delocalized over an entire [[molecule]]. The Hund–Mulliken approach or molecular orbital (MO) method is less intuitive to chemists, but has turned out capable of predicting [[spectroscopy|spectroscopic properties]] better than the VB method. This approach is the conceptual basis of the [[Hartree–Fock]] method and further [[post Hartree–Fock]] methods.
An alternative approach to valence bond theory was developed in 1929 by [[Friedrich Hund]] and [[Robert S. Mulliken]], in which [[electron]]s are described by mathematical functions delocalized over an entire [[molecule]]. The Hund–Mulliken approach or molecular orbital (MO) method is less intuitive to chemists, but has turned out capable of predicting [[spectroscopy|spectroscopic properties]] better than the VB method. This approach is the conceptual basis of the [[Hartree–Fock method]] and further [[post–Hartree–Fock|post-Hartree–Fock]] methods.


=== Density functional theory ===
=== Density functional theory ===
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{{main|Vibronic coupling}}
{{main|Vibronic coupling}}


Non-adiabatic dynamics consists of taking the interaction between several coupled potential energy surface (corresponding to different electronic [[quantum state]]s of the molecule). The coupling terms are called vibronic couplings. The pioneering work in this field was done by [[Ernst Stueckelberg|Stueckelberg]], [[Lev Davidovich Landau|Landau]], and [[Clarence Zener|Zener]] in the 1930s, in their work on what is now known as the [[Landau–Zener transition]]. Their formula allows the transition probability between two [[diabatic]] potential curves in the neighborhood of an [[avoided crossing]] to be calculated. [[Spin forbidden reactions|Spin-forbidden reactions]] are one type of non-adiabatic reactions where at least one change in [[Spin states (d electrons)|spin state]] occurs when progressing from [[Reagent|reactant]] to [[Product (chemistry)|product]].
Non-adiabatic dynamics consists of taking the interaction between several coupled potential energy surfaces (corresponding to different electronic [[quantum state]]s of the molecule). The coupling terms are called vibronic couplings. The pioneering work in this field was done by [[Ernst Stueckelberg|Stueckelberg]], [[Lev Davidovich Landau|Landau]], and [[Clarence Zener|Zener]] in the 1930s, in their work on what is now known as the [[Landau–Zener transition]]. Their formula allows the transition probability between two [[adiabatic]] potential curves in the neighborhood of an [[avoided crossing]] to be calculated. [[Spin forbidden reactions|Spin-forbidden reactions]] are one type of non-adiabatic reactions where at least one change in [[Spin states (d electrons)|spin state]] occurs when progressing from [[Reagent|reactant]] to [[Product (chemistry)|product]].


== See also ==
== See also ==
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* [[Molecular modelling]]
* [[Molecular modelling]]
* [[Physical chemistry]]
* [[Physical chemistry]]
*[[Quantum computational chemistry ]]
* [[List of quantum chemistry and solid-state physics software]]
* [[List of quantum chemistry and solid-state physics software]]
* [[QMC@Home]]
* [[QMC@Home]]
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* {{cite book |last1=Atkins|first1= P.W.|publisher=Oxford University Press|isbn= 0-19-879285-9| title=Physical Chemistry|year= 2002}}
* {{cite book |last1=Atkins|first1= P.W.|publisher=Oxford University Press|isbn= 0-19-879285-9| title=Physical Chemistry|year= 2002}}
* {{cite book |last1=Atkins|first1= P.W.|last2= Friedman|first2= R. |year=2005| title=Molecular Quantum Mechanics|publisher=Oxford University Press|edition= 4th |isbn= 978-0-19-927498-7}}
* {{cite book |last1=Atkins|first1= P.W.|last2= Friedman|first2= R. |year=2005| title=Molecular Quantum Mechanics|publisher=Oxford University Press|edition= 4th |isbn= 978-0-19-927498-7}}
* {{cite book |last1=Atkins|first1= P.W.| last2= Friedman|first2= R. |year=2008|title=Quanta, Matter and Change: A Molecular Approach to Physical Change| isbn= 978-0-7167-6117-4}}
* {{cite book |last1=Atkins|first1= P.W.| last2= Friedman|first2= R. |year=2008|title=Quanta, Matter and Change: A Molecular Approach to Physical Change|publisher= Macmillan| isbn= 978-0-7167-6117-4}}
* {{cite book |last=Bader|first=Richard|title=Atoms in Molecules: A Quantum Theory|publisher=Oxford University Press|year=1994|isbn=978-0-19-855865-1|authorlink=Richard Bader}}
* {{cite book |last=Bader|first=Richard|title=Atoms in Molecules: A Quantum Theory|publisher=Oxford University Press|year=1994|isbn=978-0-19-855865-1|authorlink=Richard Bader}}
* Gavroglu, Kostas; Ana Simões: ''Neither Physics nor Chemistry: A History of Quantum Chemistry'', MIT Press, 2011, {{ISBN|0-262-01618-4}}
* Gavroglu, Kostas; Ana Simões: ''Neither Physics nor Chemistry: A History of Quantum Chemistry'', MIT Press, 2011, {{ISBN|0-262-01618-4}}
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* {{cite book |last1=Landau | first1= L.D. |last2= Lifshitz|first2=E.M. |title=Quantum Mechanics:Non-relativistic Theory| series=Course of Theoretical Physic| year= 1977 |volume= 3 |publisher=Pergamon Press| isbn=0-08-019012-X}}
* {{cite book |last1=Landau | first1= L.D. |last2= Lifshitz|first2=E.M. |title=Quantum Mechanics:Non-relativistic Theory| series=Course of Theoretical Physic| year= 1977 |volume= 3 |publisher=Pergamon Press| isbn=0-08-019012-X}}
* {{cite book |last=Levine|first= I. |year=2008|title=Physical Chemistry|publisher=McGraw–Hill Science|edition= 6th| isbn =978-0-07-253862-5}}
* {{cite book |last=Levine|first= I. |year=2008|title=Physical Chemistry|publisher=McGraw–Hill Science|edition= 6th| isbn =978-0-07-253862-5}}
* {{cite book| last=McWeeny| first= R. |title=Coulson's Valence| year= 1979 |publisher=Oxford Science Publications|isbn= 0-19-855144-4}}
* {{Cite book|title=Coulson's valence|last=Coulson|first=Charles Alfred|publisher=Oxford University Press|year=1991|isbn=9780198551454|editor-last=McWeeny|editor-first=Roy|edition=3|oclc=468330825|orig-date=1979}}
* {{cite book| author=Pauling, L.| author-link=Linus Pauling| title=General Chemistry|publisher=Dover Publications|year=1954|isbn=0-486-65622-5|url-access=registration|url=https://archive.org/details/generalchemistry00paul_0}}
* {{cite book| author=Pauling, L.| author-link=Linus Pauling| title=General Chemistry|publisher=Dover Publications|year=1954|isbn=0-486-65622-5|url-access=registration|url=https://archive.org/details/generalchemistry00paul_0}}
* {{cite book| author1-last=Pauling|author1-first= L.| author1-link=Linus Pauling| author2-last=Wilson|author2-first= E. B. |orig-year=1935|year=1963|title=Introduction to Quantum Mechanics with Applications to Chemistry| publisher=Dover Publications| isbn =0-486-64871-0}}
* {{cite book| author1-last=Pauling|author1-first= L.| author1-link=Linus Pauling| author2-last=Wilson|author2-first= E. B. |orig-year=1935|year=1963|title=Introduction to Quantum Mechanics with Applications to Chemistry| publisher=Dover Publications| isbn =0-486-64871-0}}
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* {{cite book| last= Simon |first=Z. | year=1976| title=Quantum Biochemistry and Specific Interactions| publisher=Taylor & Francis| isbn =978-0-85626-087-2 }}
* {{cite book| last= Simon |first=Z. | year=1976| title=Quantum Biochemistry and Specific Interactions| publisher=Taylor & Francis| isbn =978-0-85626-087-2 }}
* {{cite book |last1=Szabo| first1=Attila|first2=Neil S.|last2= Ostlund|year=1996|title=Modern Quantum Chemistry: Introduction to Advanced Electronic Structure Theory|publisher= Dover| isbn= 0-486-69186-1}}
* {{cite book |last1=Szabo| first1=Attila|first2=Neil S.|last2= Ostlund|year=1996|title=Modern Quantum Chemistry: Introduction to Advanced Electronic Structure Theory|publisher= Dover| isbn= 0-486-69186-1}}

* {{Cite book|title=Handbook of computational quantum chemistry|last=Cook|first=David Branston|publisher=Oxford University Press|year=1998|isbn=9780198501145|oclc=468919475}}


== External links ==
== External links ==
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* [http://www.shodor.org/chemviz/ ChemViz Curriculum Support Resources]
* [http://www.shodor.org/chemviz/ ChemViz Curriculum Support Resources]
* [http://www.quantum-chemistry-history.com/ Early ideas in the history of quantum chemistry]
* [http://www.quantum-chemistry-history.com/ Early ideas in the history of quantum chemistry]
{{subject bar|auto=y|d=y|portal=Chemistry}}

{{BranchesofChemistry|state=expanded}}
{{BranchesofChemistry|state=expanded}}
{{Quantum mechanics topics}}
{{Quantum mechanics topics}}

Latest revision as of 18:50, 20 November 2024

Quantum chemistry, also called molecular quantum mechanics, is a branch of physical chemistry focused on the application of quantum mechanics to chemical systems, particularly towards the quantum-mechanical calculation of electronic contributions to physical and chemical properties of molecules, materials, and solutions at the atomic level.[1] These calculations include systematically applied approximations intended to make calculations computationally feasible while still capturing as much information about important contributions to the computed wave functions as well as to observable properties such as structures, spectra, and thermodynamic properties. Quantum chemistry is also concerned with the computation of quantum effects on molecular dynamics and chemical kinetics.

Chemists rely heavily on spectroscopy through which information regarding the quantization of energy on a molecular scale can be obtained. Common methods are infra-red (IR) spectroscopy, nuclear magnetic resonance (NMR) spectroscopy, and scanning probe microscopy. Quantum chemistry may be applied to the prediction and verification of spectroscopic data as well as other experimental data.

Many quantum chemistry studies are focused on the electronic ground state and excited states of individual atoms and molecules as well as the study of reaction pathways and transition states that occur during chemical reactions. Spectroscopic properties may also be predicted. Typically, such studies assume the electronic wave function is adiabatically parameterized by the nuclear positions (i.e., the Born–Oppenheimer approximation). A wide variety of approaches are used, including semi-empirical methods, density functional theory, Hartree–Fock calculations, quantum Monte Carlo methods, and coupled cluster methods.

Understanding electronic structure and molecular dynamics through the development of computational solutions to the Schrödinger equation is a central goal of quantum chemistry. Progress in the field depends on overcoming several challenges, including the need to increase the accuracy of the results for small molecular systems, and to also increase the size of large molecules that can be realistically subjected to computation, which is limited by scaling considerations — the computation time increases as a power of the number of atoms.

History

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Some view the birth of quantum chemistry as starting with the discovery of the Schrödinger equation and its application to the hydrogen atom. However, a 1927 article of Walter Heitler (1904–1981) and Fritz London is often recognized as the first milestone in the history of quantum chemistry.[2] This was the first application of quantum mechanics to the diatomic hydrogen molecule, and thus to the phenomenon of the chemical bond.[3] However, prior to this a critical conceptual framework was provided by Gilbert N. Lewis in his 1916 paper The Atom and the Molecule,[4] wherein Lewis developed the first working model of valence electrons. Important contributions were also made by Yoshikatsu Sugiura[5][6] and S.C. Wang.[7] A series of articles by Linus Pauling, written throughout the 1930s, integrated the work of Heitler, London, Sugiura, Wang, Lewis, and John C. Slater on the concept of valence and its quantum-mechanical basis into a new theoretical framework.[8] Many chemists were introduced to the field of quantum chemistry by Pauling's 1939 text The Nature of the Chemical Bond and the Structure of Molecules and Crystals: An Introduction to Modern Structural Chemistry, wherein he summarized this work (referred to widely now as valence bond theory) and explained quantum mechanics in a way which could be followed by chemists.[9] The text soon became a standard text at many universities. [10] In 1937, Hans Hellmann appears to have been the first to publish a book on quantum chemistry, in the Russian [11] and German languages.[12]

In the years to follow, this theoretical basis slowly began to be applied to chemical structure, reactivity, and bonding. In addition to the investigators mentioned above, important progress and critical contributions were made in the early years of this field by Irving Langmuir, Robert S. Mulliken, Max Born, J. Robert Oppenheimer, Hans Hellmann, Maria Goeppert Mayer, Erich Hückel, Douglas Hartree, John Lennard-Jones, and Vladimir Fock.

Electronic structure

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The electronic structure of an atom or molecule is the quantum state of its electrons.[13] The first step in solving a quantum chemical problem is usually solving the Schrödinger equation (or Dirac equation in relativistic quantum chemistry) with the electronic molecular Hamiltonian, usually making use of the Born–Oppenheimer (B–O) approximation. This is called determining the electronic structure of the molecule.[14] An exact solution for the non-relativistic Schrödinger equation can only be obtained for the hydrogen atom (though exact solutions for the bound state energies of the hydrogen molecular ion within the B-O approximation have been identified in terms of the generalized Lambert W function). Since all other atomic and molecular systems involve the motions of three or more "particles", their Schrödinger equations cannot be solved analytically and so approximate and/or computational solutions must be sought. The process of seeking computational solutions to these problems is part of the field known as computational chemistry.

Valence bond theory

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As mentioned above, Heitler and London's method was extended by Slater and Pauling to become the valence-bond (VB) method. In this method, attention is primarily devoted to the pairwise interactions between atoms, and this method therefore correlates closely with classical chemists' drawings of bonds. It focuses on how the atomic orbitals of an atom combine to give individual chemical bonds when a molecule is formed, incorporating the two key concepts of orbital hybridization and resonance.[15]

Molecular orbital theory

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An anti-bonding molecular orbital of Butadiene

An alternative approach to valence bond theory was developed in 1929 by Friedrich Hund and Robert S. Mulliken, in which electrons are described by mathematical functions delocalized over an entire molecule. The Hund–Mulliken approach or molecular orbital (MO) method is less intuitive to chemists, but has turned out capable of predicting spectroscopic properties better than the VB method. This approach is the conceptual basis of the Hartree–Fock method and further post-Hartree–Fock methods.

Density functional theory

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The Thomas–Fermi model was developed independently by Thomas and Fermi in 1927. This was the first attempt to describe many-electron systems on the basis of electronic density instead of wave functions, although it was not very successful in the treatment of entire molecules. The method did provide the basis for what is now known as density functional theory (DFT). Modern day DFT uses the Kohn–Sham method, where the density functional is split into four terms; the Kohn–Sham kinetic energy, an external potential, exchange and correlation energies. A large part of the focus on developing DFT is on improving the exchange and correlation terms. Though this method is less developed than post Hartree–Fock methods, its significantly lower computational requirements (scaling typically no worse than n3 with respect to n basis functions, for the pure functionals) allow it to tackle larger polyatomic molecules and even macromolecules. This computational affordability and often comparable accuracy to MP2 and CCSD(T) (post-Hartree–Fock methods) has made it one of the most popular methods in computational chemistry.

Chemical dynamics

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A further step can consist of solving the Schrödinger equation with the total molecular Hamiltonian in order to study the motion of molecules. Direct solution of the Schrödinger equation is called quantum dynamics, whereas its solution within the semiclassical approximation is called semiclassical dynamics. Purely classical simulations of molecular motion are referred to as molecular dynamics (MD). Another approach to dynamics is a hybrid framework known as mixed quantum-classical dynamics; yet another hybrid framework uses the Feynman path integral formulation to add quantum corrections to molecular dynamics, which is called path integral molecular dynamics. Statistical approaches, using for example classical and quantum Monte Carlo methods, are also possible and are particularly useful for describing equilibrium distributions of states.

Adiabatic chemical dynamics

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In adiabatic dynamics, interatomic interactions are represented by single scalar potentials called potential energy surfaces. This is the Born–Oppenheimer approximation introduced by Born and Oppenheimer in 1927. Pioneering applications of this in chemistry were performed by Rice and Ramsperger in 1927 and Kassel in 1928, and generalized into the RRKM theory in 1952 by Marcus who took the transition state theory developed by Eyring in 1935 into account. These methods enable simple estimates of unimolecular reaction rates from a few characteristics of the potential surface.

Non-adiabatic chemical dynamics

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Non-adiabatic dynamics consists of taking the interaction between several coupled potential energy surfaces (corresponding to different electronic quantum states of the molecule). The coupling terms are called vibronic couplings. The pioneering work in this field was done by Stueckelberg, Landau, and Zener in the 1930s, in their work on what is now known as the Landau–Zener transition. Their formula allows the transition probability between two adiabatic potential curves in the neighborhood of an avoided crossing to be calculated. Spin-forbidden reactions are one type of non-adiabatic reactions where at least one change in spin state occurs when progressing from reactant to product.

See also

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References

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  1. ^ McQuarrie, Donald A. (2007). Quantum Chemistry (2nd ed.). University Science Books. ISBN 978-1891389504.
  2. ^ Heitler, W.; London, F. (1927). "Wechselwirkung neutraler Atome und homopolare Bindung nach der Quantenmechanik". Zeitschrift für Physik. 44 (6–7): 455–472. Bibcode:1927ZPhy...44..455H. doi:10.1007/BF01397394.
  3. ^ Kołos, W. (1989). "The Origin, Development and Significance of the Heitler-London Approach". Perspectives in Quantum Chemistry. Académie Internationale Des Sciences Moléculaires Quantiques/International Academy of Quantum Molecular Science. Vol. 6. Dordrecht: Springer. pp. 145–159. doi:10.1007/978-94-009-0949-6_8. ISBN 978-94-010-6917-5.
  4. ^ Lewis, G.N. (1916). "The Atom and the Molecule". Journal of the American Chemical Society. 38 (4): 762–785. doi:10.1021/ja02261a002.
  5. ^ Sugiura, Y. (1927). "Über die Eigenschaften des Wasserstoffmoleküls im Grundzustande". Zeitschrift für Physik. 45 (7–8): 484–492. Bibcode:1927ZPhy...45..484S. doi:10.1007/BF01329207.
  6. ^ Nakane, Michiyo (2019). "Yoshikatsu Sugiura's Contribution to the Development of Quantum Physics in Japan". Berichte zur Wissenschaftsgeschichte. 42 (4): 338–356. doi:10.1002/bewi.201900007. PMID 31777981.
  7. ^ Wang, S. C. (1928-04-01). "The Problem of the Normal Hydrogen Molecule in the New Quantum Mechanics". Physical Review. 31 (4): 579–586. Bibcode:1928PhRv...31..579W. doi:10.1103/PhysRev.31.579.
  8. ^ Pauling, Linus (April 6, 1931). "The nature of the chemical bond. Application of results obtained from the quantum mechanics and from a theory of paramagnetic susceptibility to the structure of molecules". Journal of the American Chemical Society. 53 (4): 1367–1400. doi:10.1021/ja01355a027 – via Oregon State University Library.
  9. ^ Pauling, Linus (1939). The Nature of the Chemical Bond and the Structure of Molecules and Crystals: An Introduction to Modern Structural Chemistry (1st ed.). Cornell University Press.
  10. ^ Norman, Jeremy. "Pauling Publishes "The Nature of the Chemical Bond"". History of Information. Retrieved July 11, 2023.
  11. ^ Хельман, Г. (1937). Квантовая Химия. Главная Редакция Технико-Теоретической Литературы, Moscow and Leningrad.
  12. ^ Hellmann, Hans (1937). Einführung in die Quantenchemie. Deuticke, Leipzig und Wien.
  13. ^ Simons, Jack (2003). "Chapter 6. Electronic Structures". An introduction to theoretical chemistry (PDF). Cambridge, UK: Cambridge University Press. ISBN 0521823609.
  14. ^ Martin, Richard M. (2008-10-27). Electronic Structure: Basic Theory and Practical Methods. Cambridge: Cambridge University Press. ISBN 978-0-521-53440-6.
  15. ^ Shaik, S.S.; Hiberty, P.C. (2007). A Chemist's Guide to Valence Bond Theory. Wiley-Interscience. ISBN 978-0470037355.

Sources

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  • Atkins, P.W. (2002). Physical Chemistry. Oxford University Press. ISBN 0-19-879285-9.
  • Atkins, P.W.; Friedman, R. (2005). Molecular Quantum Mechanics (4th ed.). Oxford University Press. ISBN 978-0-19-927498-7.
  • Atkins, P.W.; Friedman, R. (2008). Quanta, Matter and Change: A Molecular Approach to Physical Change. Macmillan. ISBN 978-0-7167-6117-4.
  • Bader, Richard (1994). Atoms in Molecules: A Quantum Theory. Oxford University Press. ISBN 978-0-19-855865-1.
  • Gavroglu, Kostas; Ana Simões: Neither Physics nor Chemistry: A History of Quantum Chemistry, MIT Press, 2011, ISBN 0-262-01618-4
  • Karplus M., Porter R.N. (1971). Atoms and Molecules. An introduction for students of physical chemistry, Benjamin–Cummings Publishing Company, ISBN 978-0-8053-5218-4
  • Landau, L.D.; Lifshitz, E.M. (1977). Quantum Mechanics:Non-relativistic Theory. Course of Theoretical Physic. Vol. 3. Pergamon Press. ISBN 0-08-019012-X.
  • Levine, I. (2008). Physical Chemistry (6th ed.). McGraw–Hill Science. ISBN 978-0-07-253862-5.
  • Coulson, Charles Alfred (1991) [1979]. McWeeny, Roy (ed.). Coulson's valence (3 ed.). Oxford University Press. ISBN 9780198551454. OCLC 468330825.
  • Pauling, L. (1954). General Chemistry. Dover Publications. ISBN 0-486-65622-5.
  • Pauling, L.; Wilson, E. B. (1963) [1935]. Introduction to Quantum Mechanics with Applications to Chemistry. Dover Publications. ISBN 0-486-64871-0.
  • Pullman, Bernard; Pullman, Alberte (1963). Quantum Biochemistry. New York and London: Academic Press. ISBN 90-277-1830-X.
  • Scerri, Eric R. (2006). The Periodic Table: Its Story and Its Significance. Oxford University Press. ISBN 0-19-530573-6. Considers the extent to which chemistry and especially the periodic system has been reduced to quantum mechanics.
  • Simon, Z. (1976). Quantum Biochemistry and Specific Interactions. Taylor & Francis. ISBN 978-0-85626-087-2.
  • Szabo, Attila; Ostlund, Neil S. (1996). Modern Quantum Chemistry: Introduction to Advanced Electronic Structure Theory. Dover. ISBN 0-486-69186-1.
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