Free energy of spin-crossover complexes calculated with density functional methods

H. Paulsen; L. Duelund; H. Winkler; H. Toftlund; A. X. Trautwein

doi:10.1021/ic000954q

Free energy of spin-crossover complexes calculated with density functional methods

H. Paulsen, L. Duelund, H. Winkler, H. Toftlund, A. X. Trautwein^*

^*Corresponding author for this work

Institute of Physics

University of Southern Denmark

277 Citations (Scopus)

Abstract

A set of iron(II) complexes that exhibit a temperature-dependent spin-crossover between the low-spin and the high-spin state were studied by density functional methods. The total electronic energy, the zero-point vibrational energy, and the entropy were calculated in order to determine the free energy. While the calculated total energy differences between the two spin states have significant errors, qualitative agreement is achieved for the zero-point vibrational energy differences and the entropy differences.

Original language	English
Journal	Inorganic Chemistry
Volume	40
Issue number	9
Pages (from-to)	2201-2203
Number of pages	3
ISSN	0020-1669
DOIs	https://doi.org/10.1021/ic000954q
Publication status	Published - 23.04.2001

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abstract = "A set of iron(II) complexes that exhibit a temperature-dependent spin-crossover between the low-spin and the high-spin state were studied by density functional methods. The total electronic energy, the zero-point vibrational energy, and the entropy were calculated in order to determine the free energy. While the calculated total energy differences between the two spin states have significant errors, qualitative agreement is achieved for the zero-point vibrational energy differences and the entropy differences.",

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AU - Paulsen, H.

AU - Duelund, L.

AU - Winkler, H.

AU - Toftlund, H.

AU - Trautwein, A. X.

PY - 2001/4/23

Y1 - 2001/4/23

N2 - A set of iron(II) complexes that exhibit a temperature-dependent spin-crossover between the low-spin and the high-spin state were studied by density functional methods. The total electronic energy, the zero-point vibrational energy, and the entropy were calculated in order to determine the free energy. While the calculated total energy differences between the two spin states have significant errors, qualitative agreement is achieved for the zero-point vibrational energy differences and the entropy differences.

AB - A set of iron(II) complexes that exhibit a temperature-dependent spin-crossover between the low-spin and the high-spin state were studied by density functional methods. The total electronic energy, the zero-point vibrational energy, and the entropy were calculated in order to determine the free energy. While the calculated total energy differences between the two spin states have significant errors, qualitative agreement is achieved for the zero-point vibrational energy differences and the entropy differences.

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U2 - 10.1021/ic000954q

DO - 10.1021/ic000954q

M3 - Journal articles

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SP - 2201

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JO - Inorganic Chemistry

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IS - 9

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Free energy of spin-crossover complexes calculated with density functional methods

Abstract

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