Structures, Stabilities, and Bonding in CBe2, C2Be, and C2Be2

Wolfram Koch; Gernot Frenking; Jürgen Gauss; Dieter Cremer; Andrzej Sawaryn; Paul v.R. Schleyei

doi:10.1021/ja00279a012

Structures, Stabilities, and Bonding in CBe₂, C₂Be, and C₂Be₂

Wolfram Koch, Gernot Frenking, Jürgen Gauss, Dieter Cremer, Andrzej Sawaryn, Paul v.R. Schleyei

Research output: Contribution to journal › Article › peer-review

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Abstract

The structures and energies of the binary beryllium compounds CBe₂, C₂Be, and C₂Be₂ in their energetically lowest singlet and triplet states have been investigated by means of ab initio quantum chemical methods, employing second order Moller-Plesset (MP2) perturbation theory and, for the triatomic molecules, CASSCF techniques. Nonlinear geometries are predicted to be the global minima for CBe₂ (¹A₁) and C₂Be (¹A₁) by both methods, MP2/6-31G//6-31G and CASSCF using a DZ+P basis set and an active space of eight electrons in nine orbitals. For C₂Be₂, the MP2/6-31G//6-31G results favor a linear triplet isomer (³Σ_u⁺) by more than 80 kcal/mol relative to the next low-lying structure (a cyclic form, ¹A₁). The results of one electron density analysis indicate that charge transfer from Be to C is responsible for the stabilities of the nonlinear isomers and that there is little covalent CBe bonding in the singlet nonlinear minima of CBe₂ and of C₂Be.

Original language	English
Pages (from-to)	5732-5737
Number of pages	6
Journal	Journal of the American Chemical Society
Volume	108
Issue number	19
DOIs	https://doi.org/10.1021/ja00279a012
State	Published - 1 Sep 1986
Externally published	Yes

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title = "Structures, Stabilities, and Bonding in CBe2, C2Be, and C2Be2",

abstract = "The structures and energies of the binary beryllium compounds CBe2, C2Be, and C2Be2 in their energetically lowest singlet and triplet states have been investigated by means of ab initio quantum chemical methods, employing second order Moller-Plesset (MP2) perturbation theory and, for the triatomic molecules, CASSCF techniques. Nonlinear geometries are predicted to be the global minima for CBe2 (1A1) and C2Be (1A1) by both methods, MP2/6-31G//6-31G and CASSCF using a DZ+P basis set and an active space of eight electrons in nine orbitals. For C2Be2, the MP2/6-31G//6-31G results favor a linear triplet isomer (3Σu+) by more than 80 kcal/mol relative to the next low-lying structure (a cyclic form, 1A1). The results of one electron density analysis indicate that charge transfer from Be to C is responsible for the stabilities of the nonlinear isomers and that there is little covalent CBe bonding in the singlet nonlinear minima of CBe2 and of C2Be.",

author = "Wolfram Koch and Gernot Frenking and J{\"u}rgen Gauss and Dieter Cremer and Andrzej Sawaryn and Schleyei, {Paul v.R.}",

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T1 - Structures, Stabilities, and Bonding in CBe2, C2Be, and C2Be2

AU - Koch, Wolfram

AU - Frenking, Gernot

AU - Gauss, Jürgen

AU - Cremer, Dieter

AU - Sawaryn, Andrzej

AU - Schleyei, Paul v.R.

PY - 1986/9/1

Y1 - 1986/9/1

N2 - The structures and energies of the binary beryllium compounds CBe2, C2Be, and C2Be2 in their energetically lowest singlet and triplet states have been investigated by means of ab initio quantum chemical methods, employing second order Moller-Plesset (MP2) perturbation theory and, for the triatomic molecules, CASSCF techniques. Nonlinear geometries are predicted to be the global minima for CBe2 (1A1) and C2Be (1A1) by both methods, MP2/6-31G//6-31G and CASSCF using a DZ+P basis set and an active space of eight electrons in nine orbitals. For C2Be2, the MP2/6-31G//6-31G results favor a linear triplet isomer (3Σu+) by more than 80 kcal/mol relative to the next low-lying structure (a cyclic form, 1A1). The results of one electron density analysis indicate that charge transfer from Be to C is responsible for the stabilities of the nonlinear isomers and that there is little covalent CBe bonding in the singlet nonlinear minima of CBe2 and of C2Be.

AB - The structures and energies of the binary beryllium compounds CBe2, C2Be, and C2Be2 in their energetically lowest singlet and triplet states have been investigated by means of ab initio quantum chemical methods, employing second order Moller-Plesset (MP2) perturbation theory and, for the triatomic molecules, CASSCF techniques. Nonlinear geometries are predicted to be the global minima for CBe2 (1A1) and C2Be (1A1) by both methods, MP2/6-31G//6-31G and CASSCF using a DZ+P basis set and an active space of eight electrons in nine orbitals. For C2Be2, the MP2/6-31G//6-31G results favor a linear triplet isomer (3Σu+) by more than 80 kcal/mol relative to the next low-lying structure (a cyclic form, 1A1). The results of one electron density analysis indicate that charge transfer from Be to C is responsible for the stabilities of the nonlinear isomers and that there is little covalent CBe bonding in the singlet nonlinear minima of CBe2 and of C2Be.

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DO - 10.1021/ja00279a012

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JO - Journal of the American Chemical Society

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ER -

Structures, Stabilities, and Bonding in CBe₂, C₂Be, and C₂Be₂

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