Morse potential: Difference between revisions

Latest revision as of 00:18, 2 November 2025

Template:Short description Template:Sidebar with collapsible lists The Morse potential, named after physicist Philip M. Morse, is a convenient interatomic interaction model for the potential energy of a diatomic molecule. It is a better approximation for the vibrational structure of the molecule than the quantum harmonic oscillator because it explicitly includes the effects of bond breaking, such as the existence of unbound states. It also accounts for the anharmonicity of real bonds and the non-zero transition probability for overtone and combination bands. The Morse potential can also be used to model other interactions such as the interaction between an atom and a surface. Due to its simplicity (only three fitting parameters), it is not used in modern spectroscopy. However, its mathematical form inspired the MLR (Morse/Long-range) potential, which is the most popular potential energy function used for fitting spectroscopic data.

Potential energy function

File:Morse-potential.svg

The Morse potential (blue) and harmonic oscillator potential (green). Unlike the energy levels of the harmonic oscillator potential, which are evenly spaced by ħω, the Morse potential level spacing decreases as the energy approaches the dissociation energy. The dissociation energy D_e is larger than the true energy required for dissociation D₀ due to the zero point energy of the lowest (v = 0) vibrational level.

The Morse potential energy function is of the form

V (r) = D_{e} (1 - e^{- a (r - r_{e})})^{2}

Here $r$ is the distance between the atoms, $r_{e}$ is the equilibrium bond distance, $D_{e}$ is the well depth (defined relative to the dissociated atoms), and $a$ controls the 'width' of the potential (the smaller $a$ is, the larger the well). The dissociation energy of the bond can be calculated by subtracting the zero point energy $E_{0}$ from the depth of the well. The force constant (stiffness) of the bond can be found by Taylor expansion of $V^{'} (r)$ around $r = r_{e}$ to the second derivative of the potential energy function, from which it can be shown that the parameter, $a$ , is

a = \sqrt{\frac{k_{e}}{2 D_{e}}},

where $k_{e}$ is the force constant at the minimum of the well.

Since the zero of potential energy is arbitrary, the equation for the Morse potential can be rewritten any number of ways by adding or subtracting a constant value. When it is used to model the atom-surface interaction, the energy zero can be redefined so that the Morse potential becomes

V (r) = V^{'} (r) - D_{e} = D_{e} (1 - e^{- a (r - r_{e})})^{2} - D_{e}

which is usually written as

V (r) = D_{e} (e^{- 2 a (r - r_{e})} - 2 e^{- a (r - r_{e})})

where $r$ is now the coordinate perpendicular to the surface. This form approaches zero at infinite $r$ and equals $- D_{e}$ at its minimum, i.e. $r = r_{e}$ . It clearly shows that the Morse potential is the combination of a short-range repulsion term (the former) and a long-range attractive term (the latter), analogous to the Lennard-Jones potential.

Vibrational states and energies

Like the quantum harmonic oscillator, the energies and eigenstates of the Morse potential can be found using operator methods.^[1] One approach involves applying the factorization method to the Hamiltonian.

To write the stationary states on the Morse potential, i.e. solutions $Ψ_{n} (r)$ and $E_{n}$ of the following Schrödinger equation:

(- \frac{ℏ^{2}}{2 m} \frac{\partial^{2}}{\partial r^{2}} + V (r)) Ψ_{n} (r) = E_{n} Ψ_{n} (r),

it is convenient to introduce the new variables:

x \equiv a r; x_{e} \equiv a r_{e}; λ \equiv \frac{\sqrt{2 m D_{e}}}{a ℏ}; ε_{n} \equiv \frac{2 m}{a^{2} ℏ^{2}} E_{n} = \frac{λ^{2}}{D_{e}} E_{n} .

Then, the Schrödinger equation takes the simplified form:

(- \frac{\partial^{2}}{{\partial x}^{2}} + V (x)) Ψ_{n} (x) = ε_{n} Ψ_{n} (x),

V (x) = λ^{2} {(1 - e^{- (x - x_{e})})}^{2} .

Its eigenvalues (reduced by $D_{e}$ ) and eigenstates can be written as:^[2]

ε_{n} = λ^{2} - {(λ - n - \frac{1}{2})}^{2} = 2 λ (n + \frac{1}{2}) - {(n + \frac{1}{2})}^{2} = (2 λ - n - \frac{1}{2}) (n + \frac{1}{2}),

where

n = 0, 1, \dots, ⌊ λ - \frac{1}{2} ⌋,

with $⌊ x ⌋$ denoting the largest integer smaller than $x,$ and

Ψ_{n} (z) = N_{n} z^{(λ - n - \frac{1}{2})} e^{(- \frac{1}{2} z)} L_{n}^{(2 λ - 2 n - 1)} (z),

where $z \equiv 2 λ e^{- (x - x_{e})}$ and $N_{n} \equiv \sqrt{\frac{n! (2 λ - 2 n - 1) a}{Γ (2 λ - n)}}$ which satisfies the normalization condition

\int Ψ_{n}^{*} (r) Ψ_{n} (r) d r = 1

and where $L_{n}^{(α)} (z)$ is a generalized Laguerre polynomial:

L_{n}^{(α)} (z) = \frac{z^{- α} e^{z}}{n!} \frac{d^{n}}{{d z}^{n}} (z^{n + α} e^{- z}) = \frac{Γ (α + n + 1) Γ (α + 1)}{n!}_{1} F_{1} (- n, α + 1, z) .

There also exists the following analytical expression for matrix elements of the coordinate operator:^[3]

⟨ Ψ_{m} | x | Ψ_{n} ⟩ = \frac{2 (- 1)^{m - n + 1}}{(m - n) (2 N - n - m)} \sqrt{\frac{(N - n) (N - m) Γ (2 N - m + 1) m!}{Γ (2 N - n + 1) n!}} .

which is valid for $m > n$ and $N = λ - \frac{1}{2} .$

The eigenenergies in the initial variables have the form:

E_{n} = h ν_{0} (n + \frac{1}{2}) - \frac{{[h ν_{0} (n + \frac{1}{2})]}^{2}}{4 D_{e}}

where $n$ is the vibrational quantum number and $ν_{0}$ has units of frequency. The latter is mathematically related to the particle mass, $m,$ and the Morse constants via

ν_{0} = \frac{a}{2 π} \sqrt{\frac{2 D_{e}}{m}} .

Whereas the energy spacing between vibrational levels in the quantum harmonic oscillator is constant at $h ν_{0},$ the energy between adjacent levels decreases with increasing $v$ in the Morse oscillator. Mathematically, the spacing of Morse levels is

E_{n + 1} - E_{n} = h ν_{0} - \frac{(n + 1) {(h ν_{0})}^{2}}{2 D_{e}} .

This trend matches the inharmonicity found in real molecules. However, this equation fails above some value of $n_{m}$ where $E (n_{m} + 1) - E (n_{m})$ is calculated to be zero or negative. Specifically,

n_{m} = \frac{2 D_{e} - h ν_{0}}{h ν_{0}}

(integer part only).

This failure is due to the finite number of bound levels in the Morse potential, and some maximum $n_{m}$ that remains bound. For energies above $n_{m},$ all the possible energy levels are allowed and the equation for $E_{n}$ is no longer valid.

Below $n_{m},$ $E_{n}$ is a good approximation for the true vibrational structure in non-rotating diatomic molecules. In fact, the real molecular spectra are generally fit to the form¹

E_{n} / h c = ω_{e} (n + \frac{1}{2}) - ω_{e} χ_{e} {(n + \frac{1}{2})}^{2}

in which the constants $ω_{e}$ and $ω_{e} χ_{e}$ can be directly related to the parameters for the Morse potential. Specifically,

a = \sqrt{\frac{π^{2} c m ω_{e} χ_{e}}{h}}

and

D_{e} = \frac{ω_{e}}{4 χ_{e}}

Note that if $ω_{e}$ and $ω_{e} χ_{e}$ are given in ${c m}^{- 1},$ $c$ is in cm/s (not m/s), $m$ is in kg, and $h$ is in J·s; in which case $a$ will be in $m^{- 1}$ and $D_{e}$ will be in ${c m}^{- 1} .$

As is clear from dimensional analysis, for historical reasons the last equation uses spectroscopic notation in which $ω_{e}$ represents a wavenumber obeying $E = h c ω,$ and not an angular frequency given by $E = ℏ ω .$

File:N2ground.png

Harmonic oscillator (grey) and Morse (black) potentials curves are shown along with their eigenfunctions (respectively green and blue for harmonic oscillator and morse) for the same vibrational levels for nitrogen.

Morse/Long-range potential

Script error: No such module "Labelled list hatnote". An extension of the Morse potential that made the Morse form useful for modern (high-resolution) spectroscopy is the MLR (Morse/Long-range) potential.^[4] The MLR potential is used as a standard for representing spectroscopic and/or virial data of diatomic molecules by a potential energy curve. It has been used on N₂,^[5] Ca₂,^[6] KLi,^[7] MgH,^[8]^[9]^[10] several electronic states of Li₂,^[4]^[11]^[12]^[13]^[9] Cs₂,^[14]^[15] Sr₂,^[16] ArXe,^[9]^[17] LiCa,^[18] LiNa,^[19] Br₂,^[20] Mg₂,^[21] HF,^[22]^[23] HCl,^[22]^[23] HBr,^[22]^[23] HI,^[22]^[23] MgD,^[8] Be₂,^[24] BeH,^[25] and NaH.^[26] More sophisticated versions are used for polyatomic molecules.

References

¹ CRC Handbook of chemistry and physics, Ed David R. Lide, 87th ed, Section 9, SPECTROSCOPIC CONSTANTS OF DIATOMIC MOLECULES pp. 9–82
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Khordad, R; Edet, C.O; and Ikot, A.N. (2022). "Application of Morse potential and improved deformed exponential-type potential (IDEP) model to predict thermodynamics properties of diatomic molecules" International Journal of Modern Physics C 33 (08): 2250106 [1] doi:10.1142/S0129183122501066
Varshni, Yatendra Pal, (1957) "Comparative Study of Potential Energy Functions for Diatomic Molecules" Rev. Mod. Phys. 29: 664 doi:10.1103/RevModPhys.29.664
Kaplan, I.G. (2003) Handbook of Molecular Physics and Quantum Chemistry, Wiley, p207.
Haynes W M, David R and Lide T J B (eds) (2017) CRC Handbook of Chemistry and Physics, Boca Raton, FL: CRC Press

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@@ Line 108: / Line 108: @@
 :<math> D_e = \frac{ \omega_e }{\ 4 \chi_e\ } </math>
-Note that if <math>\ \omega_e\ </math> and <math>\ \omega_e\ \chi_e\ </math> are given in <math>\ \mathsf{cm}^{-1}\ ,</math> <math>\ c\ </math> is in cm/s (not m/s), <math>\ m\ </math> is in kg, and <math>\ h\ </math> is in {{nobr| [[joule (unit)|J]]·[[Second|s]] ;}} in which case <math>\ a\ </math> will be in <math>\ \mathsf{m}^{-1}\ </math> and <math>\ D_e\ </math> will be in <math>\mathsf{cm}^{-1} ~.</math>
+Note that if <math>\ \omega_e\ </math> and <math>\ \omega_e\ \chi_e\ </math> are given in <math>\ \mathsf{cm}^{-1}\ ,</math> <math>\ c\ </math> is in cm/s (not m/s), <math>\ m\ </math> is in kg, and <math>\ h\ </math> is in {{nobr| [[joule (unit)|J]]·[[Second|s]];}} in which case <math>\ a\ </math> will be in <math>\ \mathsf{m}^{-1}\ </math> and <math>\ D_e\ </math> will be in <math>\mathsf{cm}^{-1} ~.</math>
 As is clear from [[dimensional analysis]], for historical reasons the last equation uses spectroscopic notation in which <math>\ \omega_e\ </math> represents a [[wavenumber]] obeying <math>\ E = h\ c\ \omega\ ,</math> and not an [[angular frequency]] given by <math>\ E = \hbar\ \omega ~.</math>
@@ Line 115: / Line 115: @@
 == Morse/Long-range potential ==
 {{main|Morse/Long-range potential}}
-An extension of the Morse potential that made the Morse form useful for modern (high-resolution) spectroscopy is the MLR ([[Morse/Long-range potential|Morse/Long-range]]) potential.<ref name=LeRoy(A-X) /> The MLR potential is used as a standard for representing spectroscopic and/or virial data of diatomic molecules by a potential energy curve. It has been used on N<sub>2</sub>,<ref name=LeRoy(N2)>{{cite journal|last=Le Roy|first=R. J.|author2=Y. Huang |author3=C. Jary |title=An accurate analytic potential function for ground-state N<sub>2</sub> from a direct-potential-fit analysis of spectroscopic data|journal=Journal of Chemical Physics|year=2006|volume=125|issue=16|page=164310|doi=10.1063/1.2354502|pmid=17092076|bibcode=2006JChPh.125p4310L|s2cid=32249407}}</ref> Ca<sub>2</sub>,<ref name=LeRoy(Ca2)>{{cite journal|last=Le Roy|first=Robert J.|author2=R. D. E. Henderson|title=A new potential function form incorporating extended long-range behaviour: application to ground-state Ca<sub>2</sub>|journal=Molecular Physics|year=2007|volume=105|issue=5–7|pages=663–677|doi=10.1080/00268970701241656|bibcode=2007MolPh.105..663L|s2cid=94174485}}</ref> KLi,<ref name=Salami(KLi)>{{cite journal|last=Salami|first=H.|author2=A. J. Ross |author3=P. Crozet |author4=W. Jastrzebski |author5=P. Kowalczyk |author6=R. J. Le Roy |title=A full analytic potential energy curve for the a<sup>3</sup>Σ<sup>+</sup> state of KLi from a limited vibrational data set|journal=Journal of Chemical Physics|year=2007|volume=126|issue=19|page=194313|doi=10.1063/1.2734973|pmid=17523810|bibcode=2007JChPh.126s4313S|s2cid=26105905|doi-access=free}}</ref> MgH,<ref name=Henderson(MgH,MgD) /><ref name=LeRoy(damping) /><ref name=Shayesteh(MgH)>{{cite journal|last=Shayesteh|first=A.|author2=R. D. E. Henderson |author3=R. J. Le Roy |author4=P. F. Bernath |title=Ground State Potential Energy Curve and Dissociation Energy of MgH|journal=The Journal of Physical Chemistry A|year=2007|volume=111|issue=49|pages=12495–12505|doi=10.1021/jp075704a|bibcode=2007JPCA..11112495S |pmid=18020428|citeseerx=10.1.1.584.8808}}</ref> several electronic states of Li<sub>2</sub>,<ref name=LeRoy(A-X)>{{cite journal|last=Le Roy|first=Robert J.|author2=N. S. Dattani |author3=J. A. Coxon |author4=A. J. Ross |author5=Patrick Crozet |author6=C. Linton |title=Accurate analytic potentials for Li<sub>2</sub>(X) and Li<sub>2</sub>(A) from 2 to 90 Angstroms, and the radiative lifetime of Li(2p)|journal=Journal of Chemical Physics|date=25 November 2009|volume=131|issue=20|page=204309|doi=10.1063/1.3264688|pmid=19947682|bibcode=2009JChPh.131t4309L}}</ref><ref name=Dattani(c-a)>{{cite journal|last=Dattani|first=N. S.|author2=R. J. Le Roy|title=A DPF data analysis yields accurate analytic potentials for Li<sub>2</sub>(a) and Li<sub>2</sub>(c) that incorporate 3-state mixing near the c-state asymptote|journal=Journal of Molecular Spectroscopy |date=8 May 2013|volume=268|issue=1–2|pages=199–210|doi=10.1016/j.jms.2011.03.030|bibcode=  2011JMoSp.268..199D|arxiv = 1101.1361 |s2cid=119266866}}</ref><ref name=Gunton(A-X)>{{Cite journal|arxiv = 1309.5870|doi = 10.1103/PhysRevA.88.062510|title = High-resolution photoassociation spectroscopy of the <sup>6</sup>Li<sup>2</sup> ''A''(1<sup>1</sup>Σ{{su|p=+|b=u}}) state|year = 2013|last1 = Gunton|first1 = Will|last2 = Semczuk|first2 = Mariusz|last3 = Dattani|first3 = Nikesh S.|last4 = Madison|first4 = Kirk W.|journal = Physical Review A|volume = 88|issue = 6|page = 062510|bibcode = 2013PhRvA..88f2510G|s2cid = 119268157}}</ref><ref name=Semczuk(c-a)>{{cite journal|first1=M.|last1= Semczuk|first2=X.|last2= Li|first3=W.|last3= Gunton|first4=M.|last4= Haw|first5=N. S.|last5= Dattani|first6=J.|last6= Witz|first7=A. K.|last7= Mills|first8=D. J.|last8= Jones|first9=K. W.|last9= Madison |title=High-resolution photoassociation spectroscopy of the <sup>6</sup>Li<sub>2</sub> c-state|journal=Phys. Rev. A|year=2013|volume=87|issue= 5|pages=052505|doi=10.1103/PhysRevA.87.052505|url=http://pra.aps.org/abstract/PRA/v87/i5/e052505|arxiv=1309.6662|bibcode=2013PhRvA..87e2505S|s2cid= 119263860}}</ref><ref name=LeRoy(damping)>{{cite journal|last=Le Roy|first=R. J.|author2=C. C. Haugen|author3=J. Tao|author4=H. Li|title=Long-range damping functions improve the short-range behaviour of 'MLR' potential energy functions|journal=Molecular Physics|date=February 2011|volume=109|issue=3|pages=435–446|url=http://scienide2.uwaterloo.ca/~rleroy/Pubn/11MolP_damping.pdf|doi=10.1080/00268976.2010.527304|bibcode=2011MolPh.109..435L|s2cid=97119318|access-date=2013-11-30|archive-date=2019-01-08|archive-url=https://web.archive.org/web/20190108200636/http://scienide2.uwaterloo.ca/~rleroy/Pubn/11MolP_damping.pdf|url-status=dead}}</ref> Cs<sub>2</sub>,<ref name=Li(Cs2)>{{cite journal|last=Xie|first=F.|author2=L. Li |author3=D. Li |author4=V. B. Sovkov |author5=K. V. Minaev |author6=V. S. Ivanov |author7=A. M. Lyyra |author8=S. Magnier |title=Joint analysis of the Cs<sub>2</sub> a-state and 1 g (33Π1g ) states|journal=Journal of Chemical Physics|year=2011|volume=135|issue=2|page=02403|doi=10.1063/1.3606397|pmid=21766938|bibcode=2011JChPh.135b4303X}}</ref><ref name=Hajigeorgiou(Cs2)>{{cite journal|last=Coxon|first=J. A.|author2=P. G. Hajigeorgiou|title=The ground X <sup>1</sup>Σ<sup>+</sup><sub>g</sub> electronic state of the cesium dimer: Application of a direct potential fitting procedure|journal=Journal of Chemical Physics|year=2010|volume=132|issue=9|page=094105|doi=10.1063/1.3319739|bibcode=2010JChPh.132i4105C|pmid=20210387}}</ref> Sr<sub>2</sub>,<ref name=Knockel(Sr2)>{{cite journal|last=Stein|first=A.|author2=H. Knockel |author3=E. Tiemann |title=The 1S+1S asymptote of Sr<sub>2</sub> studied by Fourier-transform spectroscopy|journal=The European Physical Journal D|date=April 2010|volume=57|issue=2|pages=171–177|doi=10.1140/epjd/e2010-00058-y|bibcode=2010EPJD...57..171S|arxiv = 1001.2741 |s2cid=119243162}}</ref> ArXe,<ref name=LeRoy(damping) /><ref name=Piticco(ArXe)>{{cite journal|last=Piticco|first=Lorena|author2=F. Merkt |author3=A. A. Cholewinski |author4=F. R. W. McCourt |author5=R. J. Le Roy |title=Rovibrational structure and potential energy function of the ground electronic state of ArXe|journal=Journal of Molecular Spectroscopy|date=December 2010|volume=264|issue=2|pages=83–93|doi=10.1016/j.jms.2010.08.007|bibcode=2010JMoSp.264...83P|hdl=20.500.11850/210096|hdl-access=free}}</ref> LiCa,<ref name=Ivanova(LiCa)>{{cite journal|last=Ivanova|first=Milena|author2=A. Stein |author3=A. Pashov |author4=A. V. Stolyarov |author5=H. Knockel |author6=E. Tiemann |title=The X<sup>2</sup>Σ<sup>+</sup> state of LiCa studied by Fourier-transform spectroscopy|journal=Journal of Chemical Physics|year=2011|volume=135|issue=17|page=174303|doi=10.1063/1.3652755|bibcode=2011JChPh.135q4303I |pmid=22070298}}</ref> LiNa,<ref name=Steinke(LiNa)>{{cite journal|last=Steinke|first=M.|author2=H. Knockel |author3=E. Tiemann |title=X-state of LiNa studied by Fourier-transform spectroscopy|journal=Physical Review A|date=27 April 2012|volume=85|issue=4|page=042720|doi=10.1103/PhysRevA.85.042720|bibcode=2012PhRvA..85d2720S}}</ref> Br<sub>2</sub>,<ref name=Yukiya(Br2)>{{cite journal|last=Yukiya|first=T.|author2=N. Nishimiya |author3=Y. Samejima |author4=K. Yamaguchi |author5=M. Suzuki |author6=C. D. Boonec |author7=I. Ozier |author8=R. J. Le Roy |title=Direct-potential-fit analysis for the system of Br<sub>2</sub>|journal=Journal of Molecular Spectroscopy|date=January 2013|volume=283|pages=32–43|doi=10.1016/j.jms.2012.12.006|bibcode=2013JMoSp.283...32Y}}</ref> Mg<sub>2</sub>,<ref name=Knockel(Mg2)>{{cite journal|last=Knockel|first=H.|author2=S. Ruhmann |author3=E. Tiemann |title=The X-state of Mg2 studied by Fourier-transform spectroscopy|journal=Journal of Chemical Physics|year=2013|volume=138|issue=9|page=094303|doi=10.1063/1.4792725|pmid=23485290|bibcode=2013JChPh.138i4303K}}</ref> HF,<ref name="Li(HF, HCl, HBr, HI)">{{cite journal|last=Li|first=Gang|author2=I. E. Gordon |author3=P. G. Hajigeorgiou |author4=J. A. Coxon |author5=L. S. Rothman |title=Reference spectroscopic data for hydrogen halides, Part II:The line lists|journal=Journal of Quantitative Spectroscopy & Radiative Transfer|date=July 2013|volume=130|pages=284–295|doi=10.1016/j.jqsrt.2013.07.019|bibcode=2013JQSRT.130..284L}}</ref><ref name="sciencedirect.com">{{cite journal | doi=10.1016/j.jqsrt.2014.08.028 | volume=151 | title=Improved direct potential fit analyses for the ground electronic states of the hydrogen halides: HF/DF/TF, HCl/DCl/TCl, HBr/DBr/TBr and HI/DI/TI | journal=Journal of Quantitative Spectroscopy and Radiative Transfer | pages=133–154|bibcode = 2015JQSRT.151..133C | last1=Coxon | first1=John A. | last2=Hajigeorgiou | first2=Photos G. | year=2015 }}</ref> HCl,<ref name="Li(HF, HCl, HBr, HI)" /><ref name="sciencedirect.com"/> HBr,<ref name="Li(HF, HCl, HBr, HI)" /><ref name="sciencedirect.com"/> HI,<ref name="Li(HF, HCl, HBr, HI)" /><ref name="sciencedirect.com"/> MgD,<ref name=Henderson(MgH,MgD)>{{cite journal|last=Henderson|first=R. D. E.|author2=A. Shayesteh |author3=J. Tao |author4=C. Haugen |author5=P. F. Bernath |author6=R. J. Le Roy |title=Accurate Analytic Potential and Born–Oppenheimer Breakdown Functions for MgH and MgD from a Direct-Potential-Fit Data Analysis|journal=The Journal of Physical Chemistry A|volume=117|issue=50|pages=13373–87|date=4 October 2013|doi=10.1021/jp406680r|bibcode = 2013JPCA..11713373H |pmid=24093511|s2cid=23016118}}</ref> Be<sub>2</sub>,<ref>{{Cite journal | doi=10.1063/1.4864355|pmid = 24527923|title = Direct-potential-fit analyses yield improved empirical potentials for the ground XΣg+1 state of Be2| journal=The Journal of Chemical Physics| volume=140| issue=6| pages=064315|year = 2014|last1 = Meshkov|first1 = Vladimir V.| last2=Stolyarov| first2=Andrey V.| last3=Heaven| first3=Michael C.| last4=Haugen| first4=Carl| last5=Leroy| first5=Robert J.| bibcode=2014JChPh.140f4315M}}</ref> BeH,<ref>{{cite journal | doi=10.1016/j.jms.2014.09.005 | volume=311 | title=Beryllium monohydride (BeH): Where we are now, after 86 years of spectroscopy | journal=Journal of Molecular Spectroscopy | pages=76–83|arxiv = 1408.3301 |bibcode = 2015JMoSp.311...76D | last1=Dattani | first1=Nikesh S. | year=2015 | s2cid=118542048 }}</ref> and NaH.<ref>{{Cite journal | doi=10.1063/1.4906086|title = Dissociation energies and potential energy functions for the ground X 1Σ+ and "avoided-crossing" A 1Σ+ states of NaH| journal=The Journal of Chemical Physics| volume=142| issue=4| pages=044305|year = 2015|last1 = Walji|first1 = Sadru-Dean| last2=Sentjens| first2=Katherine M.| last3=Le Roy| first3=Robert J.|bibcode = 2015JChPh.142d4305W| pmid=25637985|s2cid = 2481313}}</ref>  More sophisticated versions are used for polyatomic molecules.
+An extension of the Morse potential that made the Morse form useful for modern (high-resolution) spectroscopy is the MLR ([[Morse/Long-range potential|Morse/Long-range]]) potential.<ref name=LeRoy(A-X) /> The MLR potential is used as a standard for representing spectroscopic and/or virial data of diatomic molecules by a potential energy curve. It has been used on N<sub>2</sub>,<ref name=LeRoy(N2)>{{cite journal|last=Le Roy|first=R. J.|author2=Y. Huang |author3=C. Jary |title=An accurate analytic potential function for ground-state N<sub>2</sub> from a direct-potential-fit analysis of spectroscopic data|journal=Journal of Chemical Physics|year=2006|volume=125|issue=16|page=164310|doi=10.1063/1.2354502|pmid=17092076|bibcode=2006JChPh.125p4310L|s2cid=32249407}}</ref> Ca<sub>2</sub>,<ref name=LeRoy(Ca2)>{{cite journal|last=Le Roy|first=Robert J.|author2=R. D. E. Henderson|title=A new potential function form incorporating extended long-range behaviour: application to ground-state Ca<sub>2</sub>|journal=Molecular Physics|year=2007|volume=105|issue=5–7|pages=663–677|doi=10.1080/00268970701241656|bibcode=2007MolPh.105..663L|s2cid=94174485}}</ref> KLi,<ref name=Salami(KLi)>{{cite journal|last=Salami|first=H.|author2=A. J. Ross |author3=P. Crozet |author4=W. Jastrzebski |author5=P. Kowalczyk |author6=R. J. Le Roy |title=A full analytic potential energy curve for the a<sup>3</sup>Σ<sup>+</sup> state of KLi from a limited vibrational data set|journal=Journal of Chemical Physics|year=2007|volume=126|issue=19|page=194313|doi=10.1063/1.2734973|pmid=17523810|bibcode=2007JChPh.126s4313S|s2cid=26105905|doi-access=free}}</ref> MgH,<ref name=Henderson(MgH,MgD) /><ref name=LeRoy(damping) /><ref name=Shayesteh(MgH)>{{cite journal|last=Shayesteh|first=A.|author2=R. D. E. Henderson |author3=R. J. Le Roy |author4=P. F. Bernath |title=Ground State Potential Energy Curve and Dissociation Energy of MgH|journal=The Journal of Physical Chemistry A|year=2007|volume=111|issue=49|pages=12495–12505|doi=10.1021/jp075704a|bibcode=2007JPCA..11112495S |pmid=18020428|citeseerx=10.1.1.584.8808}}</ref> several electronic states of Li<sub>2</sub>,<ref name=LeRoy(A-X)>{{cite journal|last=Le Roy|first=Robert J.|author2=N. S. Dattani |author3=J. A. Coxon |author4=A. J. Ross |author5=Patrick Crozet |author6=C. Linton |title=Accurate analytic potentials for Li<sub>2</sub>(X) and Li<sub>2</sub>(A) from 2 to 90 Angstroms, and the radiative lifetime of Li(2p)|journal=Journal of Chemical Physics|date=25 November 2009|volume=131|issue=20|page=204309|doi=10.1063/1.3264688|pmid=19947682|bibcode=2009JChPh.131t4309L}}</ref><ref name=Dattani(c-a)>{{cite journal|last=Dattani|first=N. S.|author2=R. J. Le Roy|title=A DPF data analysis yields accurate analytic potentials for Li<sub>2</sub>(a) and Li<sub>2</sub>(c) that incorporate 3-state mixing near the c-state asymptote|journal=Journal of Molecular Spectroscopy |date=8 May 2013|volume=268|issue=1–2|pages=199–210|doi=10.1016/j.jms.2011.03.030|bibcode=  2011JMoSp.268..199D|arxiv = 1101.1361 |s2cid=119266866}}</ref><ref name=Gunton(A-X)>{{Cite journal|arxiv = 1309.5870|doi = 10.1103/PhysRevA.88.062510|title = High-resolution photoassociation spectroscopy of the <sup>6</sup>Li<sup>2</sup> ''A''(1<sup>1</sup>Σ{{su|p=+|b=u}}) state|year = 2013|last1 = Gunton|first1 = Will|last2 = Semczuk|first2 = Mariusz|last3 = Dattani|first3 = Nikesh S.|last4 = Madison|first4 = Kirk W.|journal = Physical Review A|volume = 88|issue = 6|article-number = 062510|bibcode = 2013PhRvA..88f2510G|s2cid = 119268157}}</ref><ref name=Semczuk(c-a)>{{cite journal|first1=M.|last1= Semczuk|first2=X.|last2= Li|first3=W.|last3= Gunton|first4=M.|last4= Haw|first5=N. S.|last5= Dattani|first6=J.|last6= Witz|first7=A. K.|last7= Mills|first8=D. J.|last8= Jones|first9=K. W.|last9= Madison |title=High-resolution photoassociation spectroscopy of the <sup>6</sup>Li<sub>2</sub> c-state|journal=Phys. Rev. A|year=2013|volume=87|issue= 5|article-number=052505|doi=10.1103/PhysRevA.87.052505|url=http://pra.aps.org/abstract/PRA/v87/i5/e052505|arxiv=1309.6662|bibcode=2013PhRvA..87e2505S|s2cid= 119263860}}</ref><ref name=LeRoy(damping)>{{cite journal|last=Le Roy|first=R. J.|author2=C. C. Haugen|author3=J. Tao|author4=H. Li|title=Long-range damping functions improve the short-range behaviour of 'MLR' potential energy functions|journal=Molecular Physics|date=February 2011|volume=109|issue=3|pages=435–446|url=http://scienide2.uwaterloo.ca/~rleroy/Pubn/11MolP_damping.pdf|doi=10.1080/00268976.2010.527304|bibcode=2011MolPh.109..435L|s2cid=97119318|access-date=2013-11-30|archive-date=2019-01-08|archive-url=https://web.archive.org/web/20190108200636/http://scienide2.uwaterloo.ca/~rleroy/Pubn/11MolP_damping.pdf}}</ref> Cs<sub>2</sub>,<ref name=Li(Cs2)>{{cite journal|last=Xie|first=F.|author2=L. Li |author3=D. Li |author4=V. B. Sovkov |author5=K. V. Minaev |author6=V. S. Ivanov |author7=A. M. Lyyra |author7-link=Marjatta Lyyra|author8=S. Magnier |title=Joint analysis of the Cs<sub>2</sub> a-state and 1 g (33Π1g ) states|journal=Journal of Chemical Physics|year=2011|volume=135|issue=2|page=02403|doi=10.1063/1.3606397|pmid=21766938|bibcode=2011JChPh.135b4303X}}</ref><ref name=Hajigeorgiou(Cs2)>{{cite journal|last=Coxon|first=J. A.|author2=P. G. Hajigeorgiou|title=The ground X <sup>1</sup>Σ<sup>+</sup><sub>g</sub> electronic state of the cesium dimer: Application of a direct potential fitting procedure|journal=Journal of Chemical Physics|year=2010|volume=132|issue=9|page=094105|doi=10.1063/1.3319739|bibcode=2010JChPh.132i4105C|pmid=20210387}}</ref> Sr<sub>2</sub>,<ref name=Knockel(Sr2)>{{cite journal|last=Stein|first=A.|author2=H. Knockel |author3=E. Tiemann |title=The 1S+1S asymptote of Sr<sub>2</sub> studied by Fourier-transform spectroscopy|journal=The European Physical Journal D|date=April 2010|volume=57|issue=2|pages=171–177|doi=10.1140/epjd/e2010-00058-y|bibcode=2010EPJD...57..171S|arxiv = 1001.2741 |s2cid=119243162}}</ref> ArXe,<ref name=LeRoy(damping) /><ref name=Piticco(ArXe)>{{cite journal|last=Piticco|first=Lorena|author2=F. Merkt |author3=A. A. Cholewinski |author4=F. R. W. McCourt |author5=R. J. Le Roy |title=Rovibrational structure and potential energy function of the ground electronic state of ArXe|journal=Journal of Molecular Spectroscopy|date=December 2010|volume=264|issue=2|pages=83–93|doi=10.1016/j.jms.2010.08.007|bibcode=2010JMoSp.264...83P|hdl=20.500.11850/210096|hdl-access=free}}</ref> LiCa,<ref name=Ivanova(LiCa)>{{cite journal|last=Ivanova|first=Milena|author2=A. Stein |author3=A. Pashov |author4=A. V. Stolyarov |author5=H. Knockel |author6=E. Tiemann |title=The X<sup>2</sup>Σ<sup>+</sup> state of LiCa studied by Fourier-transform spectroscopy|journal=Journal of Chemical Physics|year=2011|volume=135|issue=17|page=174303|doi=10.1063/1.3652755|bibcode=2011JChPh.135q4303I |pmid=22070298}}</ref> LiNa,<ref name=Steinke(LiNa)>{{cite journal|last=Steinke|first=M.|author2=H. Knockel |author3=E. Tiemann |title=X-state of LiNa studied by Fourier-transform spectroscopy|journal=Physical Review A|date=27 April 2012|volume=85|issue=4|article-number=042720|doi=10.1103/PhysRevA.85.042720|bibcode=2012PhRvA..85d2720S}}</ref> Br<sub>2</sub>,<ref name=Yukiya(Br2)>{{cite journal|last=Yukiya|first=T.|author2=N. Nishimiya |author3=Y. Samejima |author4=K. Yamaguchi |author5=M. Suzuki |author6=C. D. Boonec |author7=I. Ozier |author8=R. J. Le Roy |title=Direct-potential-fit analysis for the system of Br<sub>2</sub>|journal=Journal of Molecular Spectroscopy|date=January 2013|volume=283|pages=32–43|doi=10.1016/j.jms.2012.12.006|bibcode=2013JMoSp.283...32Y}}</ref> Mg<sub>2</sub>,<ref name=Knockel(Mg2)>{{cite journal|last=Knockel|first=H.|author2=S. Ruhmann |author3=E. Tiemann |title=The X-state of Mg2 studied by Fourier-transform spectroscopy|journal=Journal of Chemical Physics|year=2013|volume=138|issue=9|page=094303|doi=10.1063/1.4792725|pmid=23485290|bibcode=2013JChPh.138i4303K}}</ref> HF,<ref name="Li(HF, HCl, HBr, HI)">{{cite journal|last=Li|first=Gang|author2=I. E. Gordon |author3=P. G. Hajigeorgiou |author4=J. A. Coxon |author5=L. S. Rothman |title=Reference spectroscopic data for hydrogen halides, Part II:The line lists|journal=Journal of Quantitative Spectroscopy & Radiative Transfer|date=July 2013|volume=130|pages=284–295|doi=10.1016/j.jqsrt.2013.07.019|bibcode=2013JQSRT.130..284L}}</ref><ref name="sciencedirect.com">{{cite journal | doi=10.1016/j.jqsrt.2014.08.028 | volume=151 | title=Improved direct potential fit analyses for the ground electronic states of the hydrogen halides: HF/DF/TF, HCl/DCl/TCl, HBr/DBr/TBr and HI/DI/TI | journal=Journal of Quantitative Spectroscopy and Radiative Transfer | pages=133–154|bibcode = 2015JQSRT.151..133C | last1=Coxon | first1=John A. | last2=Hajigeorgiou | first2=Photos G. | year=2015 }}</ref> HCl,<ref name="Li(HF, HCl, HBr, HI)" /><ref name="sciencedirect.com"/> HBr,<ref name="Li(HF, HCl, HBr, HI)" /><ref name="sciencedirect.com"/> HI,<ref name="Li(HF, HCl, HBr, HI)" /><ref name="sciencedirect.com"/> MgD,<ref name=Henderson(MgH,MgD)>{{cite journal|last=Henderson|first=R. D. E.|author2=A. Shayesteh |author3=J. Tao |author4=C. Haugen |author5=P. F. Bernath |author6=R. J. Le Roy |title=Accurate Analytic Potential and Born–Oppenheimer Breakdown Functions for MgH and MgD from a Direct-Potential-Fit Data Analysis|journal=The Journal of Physical Chemistry A|volume=117|issue=50|pages=13373–87|date=4 October 2013|doi=10.1021/jp406680r|bibcode = 2013JPCA..11713373H |pmid=24093511|s2cid=23016118}}</ref> Be<sub>2</sub>,<ref>{{Cite journal | doi=10.1063/1.4864355|pmid = 24527923|title = Direct-potential-fit analyses yield improved empirical potentials for the ground XΣg+1 state of Be2| journal=The Journal of Chemical Physics| volume=140| issue=6| page=064315|year = 2014|last1 = Meshkov|first1 = Vladimir V.| last2=Stolyarov| first2=Andrey V.| last3=Heaven| first3=Michael C.| last4=Haugen| first4=Carl| last5=Leroy| first5=Robert J.| bibcode=2014JChPh.140f4315M}}</ref> BeH,<ref>{{cite journal | doi=10.1016/j.jms.2014.09.005 | volume=311 | title=Beryllium monohydride (BeH): Where we are now, after 86 years of spectroscopy | journal=Journal of Molecular Spectroscopy | pages=76–83|arxiv = 1408.3301 |bibcode = 2015JMoSp.311...76D | last1=Dattani | first1=Nikesh S. | year=2015 | s2cid=118542048 }}</ref> and NaH.<ref>{{Cite journal | doi=10.1063/1.4906086|title = Dissociation energies and potential energy functions for the ground X 1Σ+ and "avoided-crossing" A 1Σ+ states of NaH| journal=The Journal of Chemical Physics| volume=142| issue=4| page=044305|year = 2015|last1 = Walji|first1 = Sadru-Dean| last2=Sentjens| first2=Katherine M.| last3=Le Roy| first3=Robert J.|bibcode = 2015JChPh.142d4305W| pmid=25637985|s2cid = 2481313}}</ref>  More sophisticated versions are used for polyatomic molecules.
 ==See also==

Morse potential: Difference between revisions

Latest revision as of 00:18, 2 November 2025

Contents

Potential energy function

Vibrational states and energies

Morse/Long-range potential

See also

References

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Morse potential: Difference between revisions

Latest revision as of 00:18, 2 November 2025

Potential energy function

Vibrational states and energies

Morse/Long-range potential

See also

References

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