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Molecular Physics
An International Journal at the Interface Between Chemistry and Physics
Volume 106, 2008 - Issue 12-13: A Special Issue in Honour of Professor Anthony J. Stone
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Invited Article

The dynamical polarisability and van der Waals dimer potential of mercury

K.T. Tang Department of Physics, Pacific Lutheran University, Tacoma, Washington, USACorrespondence[email protected]
&
J.P. Toennies Max-Planck Institut für Dynamik and Selbstorganisation, Göttingen, Germany
Pages 1645-1653 | Received 17 Mar 2008, Accepted 23 May 2008, Published online: 01 Dec 2010

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Peter Schwerdtfeger & Jeffrey K. Nagle. (2019) 2018 Table of static dipole polarizabilities of the neutral elements in the periodic table. Molecular Physics 117:9-12, pages 1200-1225.
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Samah Saidi, Nissrin Alharzali & Hamid Berriche. (2017) A combining rule calculation of the ground-state van der Waals potentials of the magnesium rare-gas complexes. Molecular Physics 115:8, pages 931-941.
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M.S.A. El-Kader. (2015) Collision-induced light scattering spectra of mercury vapour at different temperatures. Molecular Physics 113:11, pages 1368-1377.
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David Sulzer, Patrick Norman & Trond Saue. (2012) Atomic C 6 dispersion coefficients: a four-component relativistic Kohn–Sham study. Molecular Physics 110:19-20, pages 2535-2541.
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Articles from other publishers (35)

Almaz Khabibrakhmanov, Dmitry V. Fedorov & Alexandre Tkatchenko. (2023) Universal Pairwise Interatomic van der Waals Potentials Based on Quantum Drude Oscillators. Journal of Chemical Theory and Computation 19:21, pages 7895-7907.
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Xiaowei Sheng, Mengyuan Li & K. T. Tang. (2022) An accurate potential model for the a 3 Σ u + state of the lithium dimer . Physical Chemistry Chemical Physics 24:21, pages 13325-13334.
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L.M. Wei, Wenrui Duan, Chenchen Wang, Huihui Yang & Lei Zhang. (2021) The ground state van der Waals potentials of Cd-RG systems. Chemical Physics Letters 783, pages 139068.
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Ravi Kumar, S. Chattopadhyay, D. Angom & B. K. Mani. (2021) Relativistic coupled-cluster calculation of the electric dipole polarizability and correlation energy of Cn, , and Og: Correlation effects from lighter to superheavy elements . Physical Review A 103:6.
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Michael Schwarzer & J. Peter Toennies. (2021) Accurate semiempirical potential energy curves for the a 3Σ+-state of NaCs, KCs, and RbCs . The Journal of Chemical Physics 154:15.
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X. W. Sheng & K. T. Tang. (2021) The development of a full range analytical interatomic potential. Physical Chemistry Chemical Physics 23:13, pages 7748-7757.
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Michael Schwarzer & J. Peter Toennies. (2020) An accurate semiempirical potential energy curve for the a 3 Σ +-state of KRb . The Journal of Chemical Physics 153:11.
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L.M. Wei, P. Li, Wenrui Duan, Huihui Yang, Yanni Wen & Facheng Jin. (2020) The ground state van der Waals potentials of Zn-RG complexes (RG = He, Ne, Ar, Kr, Xe). Chemical Physics Letters 741, pages 137099.
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Bo Song & Min Yang. (2019) An empirical potential energy function for the interactions between rare gas atoms. Results in Physics 12, pages 1569-1573.
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Xiaowei Sheng, Shifeng Qian & Fengfei Hu. (2017) Van der Waals potential and vibrational energy levels of the ground state radon dimer. Chemical Physics 493, pages 111-114.
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L.M. Wei, P. Li & K.T. Tang. (2017) Iterative combining rules for the van der Waals potentials of mixed rare gas systems. Chemical Physics Letters 675, pages 40-45.
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V. N. Popov & L. R. Fokin. (2017) Calculation of the transport properties of dilute gas mixtures on the basis of model potentials. Mercury–argon system. High Temperature 55:2, pages 209-215.
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Jascha A. Lau, J. Peter Toennies & K. T. Tang. (2016) An accurate potential model for the a3Σu+ state of the alkali dimers Na2, K2, Rb2, and Cs2. The Journal of Chemical Physics 145:19.
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L.M. Wei, P. Li & K.T. Tang. (2015) The van der Waals potentials of MgCa, MgSr, MgBa, CaSr, CaBa, and SrBa. Chemical Physics Letters 635, pages 285-289.
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S. Chattopadhyay, B. K. Mani & D. Angom. (2015) Triple excitations in perturbed relativistic coupled-cluster theory and electric dipole polarizability of group-IIB elements. Physical Review A 91:5.
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Richard Hatz, Vesa Hänninen & Lauri Halonen. (2014) Pair-Potential Approach to Accurate Dispersion Energies between Group 12 (Zn, Cd, Hg) Clusters. The Journal of Physical Chemistry A 118:51, pages 12274-12279.
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L.M. Wei, P. Li & K.T. Tang. (2014) The van der Waals potentials of ZnCd, ZnHg, and CdHg. Chemical Physics Letters 614, pages 269-274.
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J. Wiebke, M. Wormit, R. Hellmann, E. Pahl & P. Schwerdtfeger. (2014) Can an Ab Initio Three-Body Virial Equation Describe the Mercury Gas Phase?. The Journal of Physical Chemistry B 118:12, pages 3392-3400.
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L. M. Wei, P. Li, L. W. Qiao & K. T. Tang. (2013) Corresponding states principle and van der Waals potentials of Zn2, Cd2, and Hg2. The Journal of Chemical Physics 139:15.
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L. R. Fokin & V. N. Popov. (2013) General function of the unit compressibility factor for liquid and gaseous mercury. High Temperature 51:4, pages 465-468.
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V. N. Popov. (2012) Thermal properties of mercury on the basis of model potentials. High Temperature 50:6, pages 700-707.
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L. W. Qiao, P. Li & K. T. Tang. (2012) Dynamic polarizabilities of Zn and Cd and dispersion coefficients involving group 12 atoms. The Journal of Chemical Physics 137:8.
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L.W. Qiao, P. Li & K.T. Tang. (2012) The van der Waals potential of mercury dimer. Chemical Physics Letters 532, pages 19-21.
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P. Li, J. Ren, N. Niu & K. T. Tang. (2011) Corresponding States Principle for the Alkaline Earth Dimers and the van der Waals Potential of Ba 2 . The Journal of Physical Chemistry A 115:25, pages 6927-6935.
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Elke Pahl, Detlev Figgen, Anastasia Borschevsky, Kirk A. Peterson & Peter Schwerdtfeger. (2011) Accurate potential energy curves for the group 12 dimers Zn2, Cd2, and Hg2. Theoretical Chemistry Accounts 129:3-5, pages 651-656.
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J Mitroy, M S Safronova & Charles W Clark. (2010) Theory and applications of atomic and ionic polarizabilities. Journal of Physics B: Atomic, Molecular and Optical Physics 43:20, pages 202001.
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P. Li, W. Xie & K. T. Tang. (2010) The van der Waals potential of the magnesium dimer. The Journal of Chemical Physics 133:8.
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Elke Pahl, Detlev Figgen, Christian Thierfelder, Kirk A. Peterson, Florent Calvo & Peter Schwerdtfeger. (2010) A highly accurate potential energy curve for the mercury dimer. The Journal of Chemical Physics 132:11.
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G. P. Yin, P. Li & K. T. Tang. (2010) The ground state van der Waals potentials of the strontium dimer and strontium rare-gas complexes. The Journal of Chemical Physics 132:7.
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Allan H. Harvey. (2010) Estimation of the Enhancement Factor for Mercury in Air. International Journal of Thermophysics 31:2, pages 297-307.
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D. D. Yang, P. Li & K. T. Tang. (2009) The ground state van der Waals potentials of the calcium dimer and calcium rare-gas complexes. The Journal of Chemical Physics 131:15.
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Alexandre Tkatchenko, Robert A. DiStasioJr.Jr., Martin Head-Gordon & Matthias Scheffler. (2009) Dispersion-corrected Møller–Plesset second-order perturbation theory. The Journal of Chemical Physics 131:9.
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X. W. Sheng, P. Li & K. T. Tang. (2009) A combining rule calculation of the ground state van der Waals potentials of the mercury rare-gas complexes. The Journal of Chemical Physics 130:17.
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M.S.A. El-Kader. (2009) Isotropic and anisotropic collision-induced light scattering spectra from high temperature gaseous mercury. Physics Letters A 373:23-24, pages 2054-2060.
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Christopher J. Cramer & Donald G. Truhlar. (2009) Density functional theory for transition metals and transition metal chemistry. Physical Chemistry Chemical Physics 11:46, pages 10757.
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