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Morse/Long-range potential

November 24, 2023

The Morse/Long-range potential (MLR potential) is an interatomic interaction model for the potential energy of a diatomic molecule. Due to the simplicity of the regular Morse potential (it only has three adjustable parameters), it is very limited in its applicability in modern spectroscopy. The MLR potential is a modern version of the Morse potential which has the correct theoretical long-range form of the potential naturally built into it.[1] It has been an important tool for spectroscopists to represent experimental data, verify measurements, and make predictions. It is useful for its extrapolation capability when data for certain regions of the potential are missing, its ability to predict energies with accuracy often better than the most sophisticated ab initio techniques, and its ability to determine precise empirical values for physical parameters such as the dissociation energy, equilibrium bond length, and long-range constants. Cases of particular note include:

  1. the c-state of dilithium (Li2): where the MLR potential was successfully able to bridge a gap of more than 5000 cm−1 in experimental data.[2] Two years later it was found that the MLR potential was able to successfully predict the energies in the middle of this gap, correctly within about 1 cm−1.[3] The accuracy of these predictions was much better than the most sophisticated ab initio techniques at the time.[4]
  2. the A-state of Li2: where Le Roy et al.[1] constructed an MLR potential which determined the C3 value for atomic lithium to a higher-precision than any previously measured atomic oscillator strength, by an order of magnitude.[5] This lithium oscillator strength is related to the radiative lifetime of atomic lithium and is used as a benchmark for atomic clocks and measurements of fundamental constants.
  3. the a-state of KLi: where the MLR was used to build an analytic global potential successfully despite there only being a small amount of levels observed near the top of the potential.[6]

Historical origins edit

The MLR potential is based on the classic Morse potential which was first introduced in 1929 by Philip M. Morse. A primitive version of the MLR potential was first introduced in 2006 by Robert J. Le Roy and colleagues for a study on N2.[7] This primitive form was used on Ca2,[8] KLi[6] and MgH,[9][10][11] before the more modern version was introduced in 2009.[1] A further extension of the MLR potential referred to as the MLR3 potential was introduced in a 2010 study of Cs2,[12] and this potential has since been used on HF,[13][14] HCl,[13][14] HBr[13][14] and HI.[13][14]

Function edit

The Morse/Long-range potential energy function is of the form

 
where for large  ,
 
so   is defined according to the theoretically correct long-range behavior expected for the interatomic interaction.

This long-range form of the MLR model is guaranteed because the argument of the exponent is defined to have long-range behavior:

 
where   is the equilibrium bond length.

There are a few ways in which this long-range behavior can be achieved, the most common is to make   a polynomial that is constrained to become   at long-range:

 
 
where n is an integer greater than 1, which value is defined by the model chosen for the long-range potential  .

It is clear to see that:

 

Applications edit

The MLR potential has successfully summarized all experimental spectroscopic data (and/or virial data) for a number of diatomic molecules, including: N2,[7] Ca2,[8] KLi,[6] MgH,[9][10][11] several electronic states of Li2,[1][2][15][3][10] Cs2,[16][12] Sr2,[17] ArXe,[10][18] LiCa,[19] LiNa,[20] Br2,[21] Mg2,[22] HF,[13][14] HCl,[13][14] HBr,[13][14] HI,[13][14] MgD,[9] Be2,[23] BeH,[24] and NaH.[25] More sophisticated versions are used for polyatomic molecules.

It has also become customary to fit ab initio points to the MLR potential, to achieve a fully analytic ab initio potential and to take advantage of the MLR's ability to incorporate the correct theoretically known short- and long-range behavior into the potential (the latter usually being of higher accuracy than the molecular ab initio points themselves because it is based on atomic ab initio calculations rather than molecular ones, and because features like spin-orbit coupling which are difficult to incorporate into molecular ab initio calculations can more easily be treated in the long-range). MLR has been used to represent ab initio points for KLi[26] and KBe.[27]

See also edit

References edit

  1. ^ a b c d Le Roy, Robert J.; N. S. Dattani; J. A. Coxon; A. J. Ross; Patrick Crozet; C. Linton (2009). "Accurate analytic potentials for Li2(X) and Li2(A) from 2 to 90 Angstroms, and the radiative lifetime of Li(2p)". Journal of Chemical Physics. 131 (20): 204309. Bibcode:2009JChPh.131t4309L. doi:10.1063/1.3264688. PMID 19947682.
  2. ^ a b Dattani, N. S.; R. J. Le Roy (8 May 2011). "A DPF data analysis yields accurate analytic potentials for Li2(a) and Li2(c) that incorporate 3-state mixing near the c-state asymptote". Journal of Molecular Spectroscopy. 268 (1–2): 199–210. arXiv:1101.1361. Bibcode:2011JMoSp.268..199D. doi:10.1016/j.jms.2011.03.030. S2CID 119266866.
  3. ^ a b Semczuk, M.; Li, X.; Gunton, W.; Haw, M.; Dattani, N. S.; Witz, J.; Mills, A. K.; Jones, D. J.; Madison, K. W. (2013). "High-resolution photoassociation spectroscopy of the 6Li2 13Σ+ state". Phys. Rev. A. 87 (5): 052505. arXiv:1309.6662. Bibcode:2013PhRvA..87e2505S. doi:10.1103/PhysRevA.87.052505. S2CID 119263860.
  4. ^ Halls, M. S.; H. B. Schlegal; M. J. DeWitt; G. F. W. Drake (18 May 2001). "Ab initio calculation of the a-state interaction potential and vibrational levels of 7Li2" (PDF). Chemical Physics Letters. 339 (5–6): 427–432. Bibcode:2001CPL...339..427H. doi:10.1016/s0009-2614(01)00403-1.
  5. ^ L-Y. Tang; Z-C. Yan; T-Y. Shi; J. Mitroy (30 November 2011). "Third-order perturbation theory for van der Waals interaction coefficients". Physical Review A. 84 (5): 052502. Bibcode:2011PhRvA..84e2502T. doi:10.1103/PhysRevA.84.052502.
  6. ^ a b c Salami, H.; A. J. Ross; P. Crozet; W. Jastrzebski; P. Kowalczyk; R. J. Le Roy (2007). "A full analytic potential energy curve for the a3Σ+ state of KLi from a limited vibrational data set". Journal of Chemical Physics. 126 (19): 194313. Bibcode:2007JChPh.126s4313S. doi:10.1063/1.2734973. PMID 17523810.
  7. ^ a b Le Roy, R. J.; Y. Huang; C. Jary (2006). "An accurate analytic potential function for ground-state N2 from a direct-potential-fit analysis of spectroscopic data". Journal of Chemical Physics. 125 (16): 164310. Bibcode:2006JChPh.125p4310L. doi:10.1063/1.2354502. PMID 17092076.
  8. ^ a b Le Roy, Robert J.; R. D. E. Henderson (2007). "A new potential function form incorporating extended long-range behaviour: application to ground-state Ca2". Molecular Physics. 105 (5–7): 663–677. Bibcode:2007MolPh.105..663L. doi:10.1080/00268970701241656. S2CID 94174485.
  9. ^ a b c Henderson, R. D. E.; A. Shayesteh; J. Tao; C. Haugen; P. F. Bernath; R. J. Le Roy (4 October 2013). "Accurate Analytic Potential and Born–Oppenheimer Breakdown Functions for MgH and MgD from a Direct-Potential-Fit Data Analysis". The Journal of Physical Chemistry A. 117 (50): 13373–87. Bibcode:2013JPCA..11713373H. doi:10.1021/jp406680r. PMID 24093511.
  10. ^ a b c d Le Roy, R. J.; C. C. Haugen; J. Tao; H. Li (February 2011). "Long-range damping functions improve the short-range behaviour of 'MLR' potential energy functions" (PDF). Molecular Physics. 109 (3): 435–446. Bibcode:2011MolPh.109..435L. doi:10.1080/00268976.2010.527304. S2CID 97119318.
  11. ^ a b Shayesteh, A.; R. D. E. Henderson; R. J. Le Roy; P. F. Bernath (2007). "Ground State Potential Energy Curve and Dissociation Energy of MgH". The Journal of Physical Chemistry A. 111 (49): 12495–12505. Bibcode:2007JPCA..11112495S. CiteSeerX 10.1.1.584.8808. doi:10.1021/jp075704a. PMID 18020428.
  12. ^ a b Coxon, J. A.; P. G. Hajigeorgiou (2010). "The ground X 1Σ+g electronic state of the cesium dimer: Application of a direct potential fitting procedure". Journal of Chemical Physics. 132 (9): 094105. Bibcode:2010JChPh.132i4105C. doi:10.1063/1.3319739. PMID 20210387.
  13. ^ a b c d e f g h Li, Gang; I. E. Gordon; P. G. Hajigeorgiou; J. A. Coxon; L. S. Rothman (2013). "Reference spectroscopic data for hydrogen halides, Part II: The line lists". Journal of Quantitative Spectroscopy & Radiative Transfer. 130: 284–295. Bibcode:2013JQSRT.130..284L. doi:10.1016/j.jqsrt.2013.07.019.
  14. ^ a b c d e f g h Coxon, John A.; Hajigeorgiou, Photos G. (2015). "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 of Quantitative Spectroscopy and Radiative Transfer. 151: 133–154. Bibcode:2015JQSRT.151..133C. doi:10.1016/j.jqsrt.2014.08.028.
  15. ^ Gunton, Will; Semczuk, Mariusz; Dattani, Nikesh S.; Madison, Kirk W. (2013). "High resolution photoassociation spectroscopy of the 6Li2 A(11Σu+) state". Physical Review A. 88 (6): 062510. arXiv:1309.5870. Bibcode:2013PhRvA..88f2510G. doi:10.1103/PhysRevA.88.062510. S2CID 119268157.
  16. ^ Xie, F.; L. Li; D. Li; V. B. Sovkov; K. V. Minaev; V. S. Ivanov; A. M. Lyyra; S. Magnier (2011). "Joint analysis of the Cs2 a-state and 1g(33Π11g) states". Journal of Chemical Physics. 135 (2): 02403. Bibcode:2011JChPh.135b4303X. doi:10.1063/1.3606397. PMID 21766938.
  17. ^ Stein, A.; H. Knockel; E. Tiemann (April 2010). "The 1S+1S asymptote of Sr2 studied by Fourier-transform spectroscopy". The European Physical Journal D. 57 (2): 171–177. arXiv:1001.2741. Bibcode:2010EPJD...57..171S. doi:10.1140/epjd/e2010-00058-y. S2CID 119243162.
  18. ^ Piticco, Lorena; F. Merkt; A. A. Cholewinski; F. R. W. McCourt; R. J. Le Roy (December 2010). "Rovibrational structure and potential energy function of the ground electronic state of ArXe". Journal of Molecular Spectroscopy. 264 (2): 83–93. Bibcode:2010JMoSp.264...83P. doi:10.1016/j.jms.2010.08.007. hdl:20.500.11850/210096.
  19. ^ Ivanova, Milena; A. Stein; A. Pashov; A. V. Stolyarov; H. Knockel; E. Tiemann (2011). "The X2Σ+ state of LiCa studied by Fourier-transform spectroscopy". Journal of Chemical Physics. 135 (17): 174303. Bibcode:2011JChPh.135q4303I. doi:10.1063/1.3652755. PMID 22070298.
  20. ^ Steinke, M.; H. Knockel; E. Tiemann (27 April 2012). "X-state of LiNa studied by Fourier-transform spectroscopy". Physical Review A. 85 (4): 042720. Bibcode:2012PhRvA..85d2720S. doi:10.1103/PhysRevA.85.042720.
  21. ^ Yukiya, T.; N. Nishimiya; Y. Samejima; K. Yamaguchi; M. Suzuki; C. D. Boonec; I. Ozier; R. J. Le Roy (January 2013). "Direct-potential-fit analysis for the system of Br2". Journal of Molecular Spectroscopy. 283: 32–43. Bibcode:2013JMoSp.283...32Y. doi:10.1016/j.jms.2012.12.006.
  22. ^ Knockel, H.; S. Ruhmann; E. Tiemann (2013). "The X-state of Mg2 studied by Fourier-transform spectroscopy". Journal of Chemical Physics. 138 (9): 094303. Bibcode:2013JChPh.138i4303K. doi:10.1063/1.4792725. PMID 23485290.
  23. ^ Meshkov, Vladimir V.; Stolyarov, Andrey V.; Heaven, Michael C.; Haugen, Carl; Leroy, Robert J. (2014). "Direct-potential-fit analyses yield improved empirical potentials for the ground X1Σg+ state of Be2". The Journal of Chemical Physics. 140 (6): 064315. Bibcode:2014JChPh.140f4315M. doi:10.1063/1.4864355. PMID 24527923.
  24. ^ Dattani, Nikesh S. (2015). "Beryllium monohydride (BeH): Where we are now, after 86 years of spectroscopy". Journal of Molecular Spectroscopy. 311: 76–83. arXiv:1408.3301. Bibcode:2015JMoSp.311...76D. doi:10.1016/j.jms.2014.09.005. S2CID 118542048.
  25. ^ Walji, Sadru-Dean; Sentjens, Katherine M.; Le Roy, Robert J. (2015). "Dissociation energies and potential energy functions for the ground X 1Σ+ and "avoided-crossing" A 1Σ+ states of NaH". The Journal of Chemical Physics. 142 (4): 044305. Bibcode:2015JChPh.142d4305W. doi:10.1063/1.4906086. PMID 25637985.
  26. ^ Xiao, Ke-La; Yang, Chuan-Lu; Wang, Mei-Shan; Ma, Xiao-Guang; Liu, Wen-Wang (2013). "The effect of inner-shell electrons on the ground and low-lying excited states of KLi: Ab initio study with all-electron basis sets". Journal of Quantitative Spectroscopy and Radiative Transfer. 129: 8–14. Bibcode:2013JQSRT.129....8X. doi:10.1016/j.jqsrt.2013.05.025.
  27. ^ Xiao, Ke-La; Yang, Chuan-Lu; Wang, Mei-Shan; Ma, Xiao-Guang; Liu, Wen-Wang (2013). "An ab initio study of the ground and low-lying excited states of KBe with the effect of inner-shell electrons". The Journal of Chemical Physics. 139 (7): 074305. Bibcode:2013JChPh.139g4305X. doi:10.1063/1.4818452. PMID 23968090.

November 24, 2023
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The Morse Long range potential MLR potential is an interatomic interaction model for the potential energy of a diatomic molecule Due to the simplicity of the regular Morse potential it only has three adjustable parameters it is very limited in its applicability in modern spectroscopy The MLR potential is a modern version of the Morse potential which has the correct theoretical long range form of the potential naturally built into it 1 It has been an important tool for spectroscopists to represent experimental data verify measurements and make predictions It is useful for its extrapolation capability when data for certain regions of the potential are missing its ability to predict energies with accuracy often better than the most sophisticated ab initio techniques and its ability to determine precise empirical values for physical parameters such as the dissociation energy equilibrium bond length and long range constants Cases of particular note include the c state of dilithium Li2 where the MLR potential was successfully able to bridge a gap of more than 5000 cm 1 in experimental data 2 Two years later it was found that the MLR potential was able to successfully predict the energies in the middle of this gap correctly within about 1 cm 1 3 The accuracy of these predictions was much better than the most sophisticated ab initio techniques at the time 4 the A state of Li2 where Le Roy et al 1 constructed an MLR potential which determined the C3 value for atomic lithium to a higher precision than any previously measured atomic oscillator strength by an order of magnitude 5 This lithium oscillator strength is related to the radiative lifetime of atomic lithium and is used as a benchmark for atomic clocks and measurements of fundamental constants the a state of KLi where the MLR was used to build an analytic global potential successfully despite there only being a small amount of levels observed near the top of the potential 6 Contents 1 Historical origins 2 Function 3 Applications 4 See also 5 ReferencesHistorical origins editThe MLR potential is based on the classic Morse potential which was first introduced in 1929 by Philip M Morse A primitive version of the MLR potential was first introduced in 2006 by Robert J Le Roy and colleagues for a study on N2 7 This primitive form was used on Ca2 8 KLi 6 and MgH 9 10 11 before the more modern version was introduced in 2009 1 A further extension of the MLR potential referred to as the MLR3 potential was introduced in a 2010 study of Cs2 12 and this potential has since been used on HF 13 14 HCl 13 14 HBr 13 14 and HI 13 14 Function editThe Morse Long range potential energy function is of the formV r D e 1 u r u r e e b r y p r e q r 2 displaystyle V r mathfrak D e left 1 frac u r u r e e beta r y p r rm eq r right 2 nbsp where for large r displaystyle r nbsp V r D e u r u r 2 4 D e displaystyle V r simeq mathfrak D e u r frac u r 2 4 mathfrak D e nbsp so u r displaystyle u r nbsp is defined according to the theoretically correct long range behavior expected for the interatomic interaction This long range form of the MLR model is guaranteed because the argument of the exponent is defined to have long range behavior b r y p r r e f r b ln 2 D e u r e displaystyle beta r y p r rm ref r simeq beta infty ln left frac 2 mathfrak D e u r e right nbsp where r e displaystyle r e nbsp is the equilibrium bond length There are a few ways in which this long range behavior can be achieved the most common is to make b r displaystyle beta r nbsp a polynomial that is constrained to become b displaystyle beta infty nbsp at long range b r 1 y p r ref r i 0 N b b i y q r ref r i y p r ref r b displaystyle beta r left 1 y p r textrm ref r right sum i 0 N beta beta i y q r textrm ref r i y p r textrm ref r beta infty nbsp y n r x r r n r x n r n r x n displaystyle y n r x r frac r n r x n r n r x n nbsp where n is an integer greater than 1 which value is defined by the model chosen for the long range potential u LR r displaystyle u text LR r nbsp It is clear to see that lim r b r b displaystyle lim r to infty beta r beta infty nbsp Applications editThe MLR potential has successfully summarized all experimental spectroscopic data and or virial data for a number of diatomic molecules including N2 7 Ca2 8 KLi 6 MgH 9 10 11 several electronic states of Li2 1 2 15 3 10 Cs2 16 12 Sr2 17 ArXe 10 18 LiCa 19 LiNa 20 Br2 21 Mg2 22 HF 13 14 HCl 13 14 HBr 13 14 HI 13 14 MgD 9 Be2 23 BeH 24 and NaH 25 More sophisticated versions are used for polyatomic molecules It has also become customary to fit ab initio points to the MLR potential to achieve a fully analytic ab initio potential and to take advantage of the MLR s ability to incorporate the correct theoretically known short and long range behavior into the potential the latter usually being of higher accuracy than the molecular ab initio points themselves because it is based on atomic ab initio calculations rather than molecular ones and because features like spin orbit coupling which are difficult to incorporate into molecular ab initio calculations can more easily be treated in the long range MLR has been used to represent ab initio points for KLi 26 and KBe 27 See also editDilithium Morse potential Lennard Jones potentialReferences edit a b c d Le Roy Robert J N S Dattani J A Coxon A J Ross Patrick Crozet C Linton 2009 Accurate analytic potentials for Li2 X and Li2 A from 2 to 90 Angstroms and the radiative lifetime of Li 2p Journal of Chemical Physics 131 20 204309 Bibcode 2009JChPh 131t4309L doi 10 1063 1 3264688 PMID 19947682 a b Dattani N S R J Le Roy 8 May 2011 A DPF data analysis yields accurate analytic potentials for Li2 a and Li2 c that incorporate 3 state mixing near the c state asymptote Journal of Molecular Spectroscopy 268 1 2 199 210 arXiv 1101 1361 Bibcode 2011JMoSp 268 199D doi 10 1016 j jms 2011 03 030 S2CID 119266866 a b Semczuk M Li X Gunton W Haw M Dattani N S Witz J Mills A K Jones D J Madison K W 2013 High resolution photoassociation spectroscopy of the 6Li2 13S state Phys Rev A 87 5 052505 arXiv 1309 6662 Bibcode 2013PhRvA 87e2505S doi 10 1103 PhysRevA 87 052505 S2CID 119263860 Halls M S H B Schlegal M J DeWitt G F W Drake 18 May 2001 Ab initio calculation of the a state interaction potential and vibrational levels of 7Li2 PDF Chemical Physics Letters 339 5 6 427 432 Bibcode 2001CPL 339 427H doi 10 1016 s0009 2614 01 00403 1 L Y Tang Z C Yan T Y Shi J Mitroy 30 November 2011 Third order perturbation theory for van der Waals interaction coefficients Physical Review A 84 5 052502 Bibcode 2011PhRvA 84e2502T doi 10 1103 PhysRevA 84 052502 a b c Salami H A J Ross P Crozet W Jastrzebski P Kowalczyk R J Le Roy 2007 A full analytic potential energy curve for the a3S state of KLi from a limited vibrational data set Journal of Chemical Physics 126 19 194313 Bibcode 2007JChPh 126s4313S doi 10 1063 1 2734973 PMID 17523810 a b Le Roy R J Y Huang C Jary 2006 An accurate analytic potential function for ground state N2 from a direct potential fit analysis of spectroscopic data Journal of Chemical Physics 125 16 164310 Bibcode 2006JChPh 125p4310L doi 10 1063 1 2354502 PMID 17092076 a b Le Roy Robert J R D E Henderson 2007 A new potential function form incorporating extended long range behaviour application to ground state Ca2 Molecular Physics 105 5 7 663 677 Bibcode 2007MolPh 105 663L doi 10 1080 00268970701241656 S2CID 94174485 a b c Henderson R D E A Shayesteh J Tao C Haugen P F Bernath R J Le Roy 4 October 2013 Accurate Analytic Potential and Born Oppenheimer Breakdown Functions for MgH and MgD from a Direct Potential Fit Data Analysis The Journal of Physical Chemistry A 117 50 13373 87 Bibcode 2013JPCA 11713373H doi 10 1021 jp406680r PMID 24093511 a b c d Le Roy R J C C Haugen J Tao H Li February 2011 Long range damping functions improve the short range behaviour of MLR potential energy functions PDF Molecular Physics 109 3 435 446 Bibcode 2011MolPh 109 435L doi 10 1080 00268976 2010 527304 S2CID 97119318 a b Shayesteh A R D E Henderson R J Le Roy P F Bernath 2007 Ground State Potential Energy Curve and Dissociation Energy of MgH The Journal of Physical Chemistry A 111 49 12495 12505 Bibcode 2007JPCA 11112495S CiteSeerX 10 1 1 584 8808 doi 10 1021 jp075704a PMID 18020428 a b Coxon J A P G Hajigeorgiou 2010 The ground X 1S g electronic state of the cesium dimer Application of a direct potential fitting procedure Journal of Chemical Physics 132 9 094105 Bibcode 2010JChPh 132i4105C doi 10 1063 1 3319739 PMID 20210387 a b c d e f g h Li Gang I E Gordon P G Hajigeorgiou J A Coxon L S Rothman 2013 Reference spectroscopic data for hydrogen halides Part II The line lists Journal of Quantitative Spectroscopy amp Radiative Transfer 130 284 295 Bibcode 2013JQSRT 130 284L doi 10 1016 j jqsrt 2013 07 019 a b c d e f g h Coxon John A Hajigeorgiou Photos G 2015 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 of Quantitative Spectroscopy and Radiative Transfer 151 133 154 Bibcode 2015JQSRT 151 133C doi 10 1016 j jqsrt 2014 08 028 Gunton Will Semczuk Mariusz Dattani Nikesh S Madison Kirk W 2013 High resolution photoassociation spectroscopy of the 6Li2 A 11Su state Physical Review A 88 6 062510 arXiv 1309 5870 Bibcode 2013PhRvA 88f2510G doi 10 1103 PhysRevA 88 062510 S2CID 119268157 Xie F L Li D Li V B Sovkov K V Minaev V S Ivanov A M Lyyra S Magnier 2011 Joint analysis of the Cs2 a state and 1g 33P11g states Journal of Chemical Physics 135 2 02403 Bibcode 2011JChPh 135b4303X doi 10 1063 1 3606397 PMID 21766938 Stein A H Knockel E Tiemann April 2010 The 1S 1S asymptote of Sr2 studied by Fourier transform spectroscopy The European Physical Journal D 57 2 171 177 arXiv 1001 2741 Bibcode 2010EPJD 57 171S doi 10 1140 epjd e2010 00058 y S2CID 119243162 Piticco Lorena F Merkt A A Cholewinski F R W McCourt R J Le Roy December 2010 Rovibrational structure and potential energy function of the ground electronic state of ArXe Journal of Molecular Spectroscopy 264 2 83 93 Bibcode 2010JMoSp 264 83P doi 10 1016 j jms 2010 08 007 hdl 20 500 11850 210096 Ivanova Milena A Stein A Pashov A V Stolyarov H Knockel E Tiemann 2011 The X2S state of LiCa studied by Fourier transform spectroscopy Journal of Chemical Physics 135 17 174303 Bibcode 2011JChPh 135q4303I doi 10 1063 1 3652755 PMID 22070298 Steinke M H Knockel E Tiemann 27 April 2012 X state of LiNa studied by Fourier transform spectroscopy Physical Review A 85 4 042720 Bibcode 2012PhRvA 85d2720S doi 10 1103 PhysRevA 85 042720 Yukiya T N Nishimiya Y Samejima K Yamaguchi M Suzuki C D Boonec I Ozier R J Le Roy January 2013 Direct potential fit analysis for the system of Br2 Journal of Molecular Spectroscopy 283 32 43 Bibcode 2013JMoSp 283 32Y doi 10 1016 j jms 2012 12 006 Knockel H S Ruhmann E Tiemann 2013 The X state of Mg2 studied by Fourier transform spectroscopy Journal of Chemical Physics 138 9 094303 Bibcode 2013JChPh 138i4303K doi 10 1063 1 4792725 PMID 23485290 Meshkov Vladimir V Stolyarov Andrey V Heaven Michael C Haugen Carl Leroy Robert J 2014 Direct potential fit analyses yield improved empirical potentials for the ground X1Sg state of Be2 The Journal of Chemical Physics 140 6 064315 Bibcode 2014JChPh 140f4315M doi 10 1063 1 4864355 PMID 24527923 Dattani Nikesh S 2015 Beryllium monohydride BeH Where we are now after 86 years of spectroscopy Journal of Molecular Spectroscopy 311 76 83 arXiv 1408 3301 Bibcode 2015JMoSp 311 76D doi 10 1016 j jms 2014 09 005 S2CID 118542048 Walji Sadru Dean Sentjens Katherine M Le Roy Robert J 2015 Dissociation energies and potential energy functions for the ground X 1S and avoided crossing A 1S states of NaH The Journal of Chemical Physics 142 4 044305 Bibcode 2015JChPh 142d4305W doi 10 1063 1 4906086 PMID 25637985 Xiao Ke La Yang Chuan Lu Wang Mei Shan Ma Xiao Guang Liu Wen Wang 2013 The effect of inner shell electrons on the ground and low lying excited states of KLi Ab initio study with all electron basis sets Journal of Quantitative Spectroscopy and Radiative Transfer 129 8 14 Bibcode 2013JQSRT 129 8X doi 10 1016 j jqsrt 2013 05 025 Xiao Ke La Yang Chuan Lu Wang Mei Shan Ma Xiao Guang Liu Wen Wang 2013 An ab initio study of the ground and low lying excited states of KBe with the effect of inner shell electrons The Journal of Chemical Physics 139 7 074305 Bibcode 2013JChPh 139g4305X doi 10 1063 1 4818452 PMID 23968090 Retrieved from https en wikipedia org w index php title Morse Long range potential amp oldid 1170001446, wikipedia, wiki, book, books, library,

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