SCM: ADF User's Guide

6 References

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32. Johnson, B.G., P.M.W. Gill, and J.A. Pople, The performance of a family of density functional methods. Journal of Chemical Physics, 1993. 98(7): p. 5612.

33. Russo, T.V., R.L. Martin, and P.J. Hay, Density Functional calculations on first-row transition metals. Journal of Chemical Physics, 1994. 101(9): p. 7729.

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38. Boese, A.D. and N.C. Handy, A new parametrization of exchange-correlation generalized gradient approximation functionals. Journal of Chemical Physics, 2001. 114: p. 5497-5503.

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40. Krieger, J.B., J. Chen, G.J. Iafrate, and A. Savin, in Electron Correlations and Materials Properties, A. Gonis and N. Kioussis, Editors. 1999, Plenum: New York.

41. Perdew, J.P., S. Kurth, A. Zupan, and P. Blaha, Physical Review Letters, 1999. 82: p. 5179.

42. van Voorhis, T. and G.E. Scuseria, Journal of Chemical Physics, 1998. 109: p. 400.

43. Filatov, M. and W. Thiel, Molecular Physics, 1997. 91: p. 847.

44. Filatov, M. and W. Thiel, Physical Review A, 1998. 57: p. 189.

45. Proynov, E.I., S. Sirois, and D.R. Salahub, International Journal of Quantum Chemistry, 1997. 64: p. 427.

46. Proynov, E.I., H. Chermette, and D.R. Salahub, Journal of Chemical Physics, 2000. 113: p. 10013.

47. Patchkovskii, S., J. Autschbach, and T. Ziegler, Curing difficult cases in magnetic properties prediction with self-interaction corrected density functional theory. Journal of Chemical Physics, 2001. 115: p. 26-42.

48. Patchkovskii, S. and T. Ziegler, Improving `difficult' reaction barriers with self-interaction corrected density functional theory. Journal of Chemical Physics, 2002. 116: p. 7806.

49. Patchkovskii, S. and T. Ziegler, "Phosphorus NMR chemical shifts with self-interaction free, gradient-corrected DFT. Journal of Physical Chemistry, 2002. A 106: p. 1088.

50. Philipsen, P.H.T., E. van Lenthe, J.G. Snijders and E.J. Baerends, Relativistic calculations on the adsorption of CO on the (111) surfaces of Ni, Pd, and Pt within the zeroth-order regular approximation. Physical Review B, 1997. 56(20): p. 13556-13562.

51. Snijders, J.G. and E.J. Baerends, A perturbation theory approach to relativistic calculations. I. Atoms. Molecular Physics, 1978. 36: p. 1789.

52. Snijders, J.G., E.J. Baerends, and P. Ros, A perturbation theory approach to relativistic calculations. II. Molecules. Molecular Physics, 1979. 38: p. 1909.

53. Ziegler, T., J.G. Snijders, and E.J. Baerends, Relativistic effects on bonding. Journal of Chemical Physics, 1981. 74: p. 1271.

54. DeKock, R.L., E.J. Baerends, P.M. Boerrigter and J.G. Snijders, On the nature of the first excited states of the uranyl ion. Chemical Physics Letters, 1984. 105: p. 308.

55. DeKock, R.L., E.J. Baerends, P.M. Boerrigter and R. Hengelmolen, Electronic structure and bonding of Hg(CH₃)₂, Hg(CN)₂, Hg(CH₃)(CN), Hg(CCCH₃)₂, and Au(PMe)₃)(CH₃). Journal of the American Chemical Society, 1984. 106: p. 33387.

56. Boerrigter, P.M., Spectroscopy and bonding of heavy element compounds. 1987, Vrije Universiteit.

57. Boerrigter, P.M., M.A. Buijse, and J.G. Snijders, Spin-Orbit interaction in the excited states of the dihalogen ions F2+, Cl2+ an Br2+. Chemical Physics, 1987. 111: p. 47-53.

58. Boerrigter, P.M., E.J. Baerends, and J.G. Snijders, A relativistic LCAO Hartree-Fock-Slater investigation of the electronic structure of the actinocenes M(COT)₂, M=Th, Pa, U, Np and Pu. Chemical Physics, 1988. 122: p. 357-374.

59. Ziegler, T., V. Tschinke, E.J. Baerends, J.G. Snijders and W. Ravenek, Calculation of bond energies in compounds of heavy elements by a quasi-relativistic approach. Journal of Physical Chemistry, 1989. 93: p. 3050-3056.

60. Li, J., G. Schreckenbach, and T. Ziegler, Journal of the American Chemical Society, 1995. 117: p. 486.

61. van Lenthe, E., A.E. Ehlers, and E.J. Baerends, Geometry optimization in the Zero Order Regular Approximation for relativistic effects. Journal of Chemical Physics, 1999. 110: p. 8943-8953.

62. van Lenthe, E., E.J. Baerends, and J.G. Snijders, Relativistic regular two-component Hamiltonians. Journal of Chemical Physics, 1993. 99: p. 4597.

63. van Lenthe, E., E.J. Baerends, and J.G. Snijders, Relativistic total energy using regular approximations. Journal of Chemical Physics, 1994. 101(11): p. 9783.

64. van Lenthe, E., J.G. Snijders, and E.J. Baerends, The zero-order regular approximation for relativistic effects: The effect of spin-orbit coupling in closed shell molecules. J. Chem. Phys., 1996. 105(15): p. 6505-6516.

65. van Lenthe, E., R. van Leeuwen, E.J. Baerends, and J.G. Snijders, Relativistic regular two-component Hamiltonians. International Journal of Quantum Chemistry, 1996. 57: p. 281 -293.

66. Pye, C.C. and T. Ziegler, Theoretical Chemistry Accounts, 1999. 101: p. 396-408.

67. Klamt, A. and G. Schüürmann, COSMO: a new approach to dielectric screening in solvents with explicit expressions for the screening energy and its gradient. Journal of the Chemical Society: Perkin Transactions, 1993. 2: p. 799-805.

68. Klamt, A., Conductor-like Screening Model for real solvents: A new approach to the quantitative calculation of solvation phenomena. Journal of Physical Chemistry, 1995. 99: p. 2224-2235.

69. Klamt, A. and V. Jones, Treatment of the outlying charge in continuum solvation models. Journal of Chemical Physics, 1996. 105: p. 9972-9981.

70. Pascual-Ahuir, J.L., E. Silla, and I. Tunon, Journal of Computational Chemistry, 1994. 15: p. 1127.

71. van Gisbergen, S.J.A., J.G. Snijders, and E.J. Baerends, Computer Physics Communications, 1999. 118: p. 119-138.

72. van Gisbergen, S.J.A., Molecular Response Property Calculations using Time Dependent Density Functional Theory, in Chemistry. 1998, Vrije Universiteit: Amsterdam. p. 190.

73. Gross, E.K.U., J.F. Dobson, and Petersilka, in Density Functional Theory, R.F. Nalewajski, Editor. 1996, Springer: Heidelberg.

74. van Gisbergen, S.J.A., V.P. Osinga, O.V. Gritsenko, R. van Leeuwen, J.G. Snijders and E.J. Baerends, Improved density functional theory results for frequency-dependent polarizabilities, by the use of an exchange-correlation potential with correct asymptotic behavior. Journal of Chemical Physics, 1996. 105(7): p. 3142.

75. van Gisbergen, S.J.A., J.G. Snijders, and E.J. Baerends, Physical Review Letters, 1997. 78: p. 3097.

76. van Gisbergen, S.J.A., J.G. Snijders, and E.J. Baerends, Calculating frequency-dependent hyperpolarizabilities using time-dependent density functional theory. Journal of Chemical Physics, 1998. 109: p. 10644-10656.

77. van Gisbergen, S.J.A., J.G. Snijders, and E.J. Baerends, Accurate density functional calculations on frequency-dependent hyperpolarizabilities of small molecules. Journal of Chemical Physics, 1998. 109: p. 10657-10668.

78. Casida, M.E., C. Jamorski, K.C. Casida, and D.R. Salahub, Journal of Chemical Physics, 1998. 108: p. 4439.

79. Osinga, V.P., S.J.A. van Gisbergen, J.G. Snijders and E.J. Baerends, Journal of Chemical Physics, 1997. 106: p. 5091.

80. Autschbach, J. and T. Ziegler, Calculating molecular electric and magnetic properties from time-dependent density functional response theory. Journal of Chemical Physics, 2002. 116: p. 891-896.

81. Autschbach, J., T. Ziegler, S.J.A. van Gisbergen, and E.J. Baerends, CD. Journal of Chemical Physics, 2002. 116: p. 6930.

82. van Gisbergen, S.J.A., F. Kootstra, P.R.T. Schipper, O.V. Gritsenko, J.G. Snijders, and E.J. Baerends, Physical Review A, 1998. 57: p. 2556.

83. van Gisbergen, S.J.A., A. Rosa, G. Ricciardi, and E.J. Baerends, Journal of Chemical Physics, 1999. 111: p. 2499.

84. Rosa, A., G. Ricciardi, E.J. Baerends, S.J.A. van Gisbergen, The Optical Spectra of NiP, Nipz, NiTBP, and NiPc. Electronic effects of meso-tetraaza substitution and tetrabenzoannulation. Journal of Physical Chemistry A, 2001. 105: p. 3311-3327.

85. Ricciardi, G., A. Rosa, and E.J. Baerends, Ground and Excited States of Zinc Phthalocyanine studied by Density Functional Methods. Journal of Physical Chemistry A, 2001. 105: p. 5242-5254.

86. van Gisbergen, S.J.A., J.A. Groeneveld, A. Rosa, J.G. Snijders and E.J.Baerends, Excitation energies for transition metal compounds from time-dependent density functional theory. Applications to MnO4-, Ni(CO)4 and Mn2(CO)10. Journal of Physical Chemistry A, 1999. 103: p. 6835-6844.

87. Rosa, A., E.J. Baerends, S.J.A. van Gisbergen, E. van Lenthe, J.A. Groeneveld and J. G. Snijders, Journal of the American Chemical Society, 1999. 121: p. 10356-10365.

88. van Gisbergen, S.J.A., C. Fonseca Guerra, and E.J. Baerends, Towards excitation energies and (hyper)polarizability calculations of large molecules. Application of parallelization and linear scaling techniques to time-dependent density functional response theory. Journal of Computational Chemistry, 2000. 21: p. 1511-1523.

89. van Gisbergen, S.J.A., J.G. Snijders, and E.J. Baerends, A Density Functional Theory study of frequency-dependent polarizabilities and van der Waals dispersion coefficients for polyatomic molecules. Journal of Chemical Physics, 1995. 103: p. 9347-9354.

90. Champagne, B., E.A. Perpète, S.J.A. van Gisbergen, E.J. Baerends, J.G. Snijders, C. Soubra-Ghaoui, K.A. Robins, and B.Kirtman, Assessment of conventional density functional schemes for computing the polarizabilities and hyperpolarizabilities of conjugated oligomers: An ab initio investigation of polyacetylene chains. Journal of Chemical Physics, 1998. 109: p. 10489-10498. Erratum: J. Chem. Phys., 1999 111: 6652

91. Bishop, D.M., Advances in Quantum Chemistry, 1994. 25: p. 3.

92. Willets, A., J.E. Rice, D.M. Burland, and D.P. Shelton, Problems in comparison of experimental and theoretical hyperpolarizabilities. Journal of Chemical Physics, 1992. 97: p. 7590.

93. Shelton, D.P. and J.E. Rice, Chemical Reviews, 1994. 94: p. 3.

94. Autschbach, J., S. Patchkovskii, T. Ziegler, S.J.A. van Gisbergen, and E.J. Baerends, ORD. Journal of Chemical Physics, 2002. 117: p. 581.

95. van Lenthe, E., A. van der Avoird, and P.E.S. Wormer, Density functional calculations of molecular g-tensors in the zero order regular approximation for relativistic effects. Journal of Chemical Physics, 1997. 107: p. 2488-2498.

96. van Lenthe, E., A. van der Avoird, and P.E.S. Wormer, Density functional calculations of molecular hyperfine interactions in the zero order regular approximation for relativistic effects. Journal of Chemical Physics, 1998. 108(12): p. 4783-4796.

97. van Lenthe, E. and E.J. Baerends, Density functional calculations of nuclear quadrupole coupling constants in the zero-order regular approximation for relativistic effects. Journal of Chemical Physics, 2000. 112(19): p. 8279-8292.

98. Bulo, R.E., A.W. Ehlers, S. Grimme, and K. Lammertsma, Journal of the American Chemical Society, 2002. 124: p. 13903.

99. Pauncz, R., Spin Eigenfunctions. 1979, New York: Plenum Press.

100. Szabo, A. and N.S. Ostlund, Modern Quantum Chemistry. 1st ed. revised ed. 1989: McGraw-Hill.

101. Eschrig, H. and V.D.P. Servedio, Relativistic density functional approach to open shells. Journal of Computational Chemistry, 1999. 20: p. 23.

102. Wullen, C.v., Spin densities in two-component relativistic density functional calculations: Noncollinear versus collinear approach. Journal of Computational Chemistry, 2002. 23: p. 779.

103. Wang, S.G. and W.H.E. Schwarz, Simulation of nondynamical correlation in density functional calculations by the optimized fractional orbital occupation approach: Application to the potential energy surfaces of O₃ and SO₂. Journal of Chemical Physics, 1996. 105(11): p. 4641.

104. Boerrigter, P.M., G. te Velde, and E.J. Baerends, Three-dimensional Numerical Integration for Electronic Structure Calculations. International Journal of Quantum Chemistry, 1988. 33: p. 87.

105. te Velde, G. and E.J. Baerends, Numerical Integration for Polyatomic Systems. Journal of Computational Physics, 1992. 99(1): p. 84-98.

106. Bérces, A. and T. Ziegler, Chemical Physics Letters, 1993. 203(5-6): p. 592.

107. Bérces, A. and T. Ziegler, Journal of Chemical Physics, 1993. 98: p. 4793.

108. Bérces, A. and T. Ziegler, The harmonic force field of benzene. A local density functional study. Journal of Chemical Physics, 1993. 98: p. 4793.

109. te Velde, G., Numerical integration and other methodological aspects of bandstructure calculations, in Chemistry. 1990, Vrije Universiteit: Amsterdam.

110. Ziegler, T. and A. Rauk, On the calculation of Bonding Energies by the Hartree Fock Slater method. Theoretica Chimica Acta, 1977. 49: p. 143.

111. Noodleman, L. and E.J. Baerends, Electronic Structure, Magnetic Properties, ESR, and Optical Spectra for 2-Fe Ferredoxin Models by LCAO-Xa Valence Bond Theory. Journal of the American Chemical Society, 1984. 106: p. 2316.

112. Bickelhaupt, F.M., N.M. Nibbering, E.M. van Wezenbeek and E.J. Baerends, The Central Bond in the Three CN* Dimers NC_CN, CN-CN, and CN-NC: Electron Pair Bonding and Pauli Repulsion Effects. Journal of Physical Chemistry, 1992. 96(12): p. 4864.

113. Schreckenbach, G. and T. Ziegler, The calculation of NMR shielding tensors using GIAO's and modern density functional theory. Journal of Physical Chemistry, 1995. 99: p. 606.

114. Schreckenbach, G. and T. Ziegler, The calculation of NMR shielding tensors based on density functional theory and the frozen-core approximation. International Journal of Quantum Chemistry, 1996. 60: p. 753-766.

115. Schreckenbach, G. and T. Ziegler, Calculation of NMR shielding tensors based on density functional theory and a scalar relativistic Pauli-type Hamiltonian. The application to transition metal complexes. International Journal of Quantum Chemistry, 1997. 61: p. 899.

116. Wolff, S.K. and T. Ziegler, Calculation of DFT-GIAO NMR shifts with inclusion of spin-orbit coupling. Journal of Chemical Physics, 1998. 109: p. 895.

117. Wolff, S.K., T. Ziegler, E. van Lenthe, and E.J. Baerends, Density functional calculations of nuclear magnetic shieldings using the zeroth-order regular approximation for relativistic effects: ZORA NMR. Journal of Chemical Physics, 1999. 110: p. 7689.

118. Autschbach, J. and T. Ziegler, Nuclear spin-spin coupling constants from regular approximate density functional calculations. I. Formalism and scalar relativistic results for heavy metal compounds. Journal of Chemical Physics, 2000. 113: p. 936-947.

119. Autschbach, J. and T. Ziegler, Nuclear spin-spin coupling constants from regular approximate relativistic density functional calculations. II. Spin-orbit coupling effects and anisotropies. Journal of Chemical Physics, 2000. 113: p. 9410-9418.

120. Schreckenbach, G. and T. Ziegler, Calculation of the G-tensor of electron paramagnetic resonance spectroscopy using Gauge-Including Atomic Orbitals and Density Functional Theory. Journal of Physical Chemistry A, 1997. 101: p. 3388-3399.

121. Patchkovskii, S. and T. Ziegler, Journal of Physical Chemistry, 2001. A105: p. 5490.

122. Edmiston, C. and K. Rüdenberg, Rev. Mod. Phys., 1963. 35: p. 457.

123. Boys, S.F., Rev. Mod. Phys., 1960. 32: p. 253.

124. von Niessen, W., Journal of Chemical Physics, 1967. 47: p. 253.

125. Hirshfeld, F.L., Theoretica Chimica Acta, 1977. 44: p. 129.

126. Wiberg, K.B. and P.R. Rablen, Comparison of atomic charges derived via different procedures. J. Comp. Chem., 1993. 14(12): p. 1504.

127. Bickelhaupt, N.J.R. van Eikema Hommes, C. Fonseca Guerra, and E.J. Baerends, The Carbon-Lithium Electron Pair Bond in (CH3Li)n (n = 1, 2, 4). Organometallics, 1996. 15: p. 2923.

128. C. Fonseca Guerra, J.-W. Handgraaf, E. J. Baerends, F. M. Bickelhaupt, Voronoi Deformation Density (VDD) charges. Assessment of the Mulliken, Bader, Hirshfeld, Weinhold and VDD methods for Charge Analysis, J. Comput. Chem. 2004, 25, p. 189.

129. Fonseca Guerra, C., F.M. Bickelhaupt, J.G. Snijders, E.J. Baerends, Chemical European Journal, 1999. 5: p. 3581-3594.

130. Kitaura, K. and K. Morokuma, International Journal of Quantum Chemistry, 1976. 10: p. 325.

131. Ziegler, T. and A. Rauk, Inorganic Chemistry, 1979. 18: p. 1755.

132. Fujimoto, H., J. Osamura, and T. Minato, Journal of the American Chemical Society, 1978. 100: p. 2954.

133. Wolfe, S., D.J. Mitchell, and M.H. Whangbo, Journal of the American Chemical Society, 1978. 100: p. 1936.

134. Stone, A.J. and R.W. Erskine, Journal of the American Chemical Society, 1980. 102: p. 7185.

135. Bernardi, F., A. Bottoni, A. Mangini, and G. Tonachini, THEOCHEM-Journal of Molecular Structure, 1981. 3: p. 163.

136. van den Hoek, P.J. and E.J. Baerends, Chemical bonding at metal-semiconductor interfaces. Applied Surface Science, 1989. 41/42: p. 236.

137. Autschbach, J., On the calculation of relativistic effects and how to understand their trends in atoms and molecules, in Chemistry. 1999, University of Siegen: Siegen.

138. M.A. Watson, N.C. Handy, and A.J. Cohen, Journal of Chemical Physics, 2003. 119: p. 6475.

139. Ö. Farkas and H.B. Schlegel, Physical Chemistry Chemical Physics, 2002. 4: p. 11.

140. I. Mayer, Charge, bond order and valence in the ab inition SCF theory, Chemical Physics Letters, 1983. 97: p. 270.

141. L. Jensen, P.T. van Duijnen, and J.G. Snijders, Journal of Chemical Physics, 2003 118: p. 514

142. L. Jensen, P.T. van Duijnen, and J.G. Snijders, Journal of Chemical Physics, 2003 119: p. 3800

143. L. Jensen, P.T. van Duijnen, and J.G. Snijders, Journal of Chemical Physics, 2003 119: p. 12998

144. L. Jensen, M. Swart, and P.T. van Duijnen, Journal of Chemical Physics, 2005 122: p. 034103

145. L. Jensen, Modelling of optical response properties: Application to nanostructures, PhD thesis, Rijksuniversiteit Groningen, 2004.

146. P.T. van Duijnen and M. Swart, Journal of Physical Chemistry A, 1998 102, p. 2399

147. L. Jensen, P.-O. Astrand, A. Osted, J. Kongsted, and K.V. Mikkelsen, Journal of Chemical Physics, 2002 116: p. 4001