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Valence Bond Theory and Hybridized Orbitals02:38

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According to valence bond theory, a covalent bond results when: (1) an orbital on one atom overlaps an orbital on a second atom, and (2) the single electrons in each orbital combine to form an electron pair. The strength of a covalent bond depends on the extent of overlap of the orbitals involved. Maximum overlap is possible when the orbitals overlap on a direct line between the two nuclei.
A σ bond (single bond in a Lewis structure) is a covalent bond in which the electron density is...
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The molecular orbital theory describes the distribution of electrons in molecules in a manner similar to the distribution of electrons in atomic orbitals. The region of space in which a valence electron in a molecule is likely to be found is called a molecular orbital. Mathematically, the linear combination of atomic orbitals (LCAO) generates molecular orbitals. Combinations of in-phase atomic orbital wave functions result in regions with a high probability of electron density, while...
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Coordination compounds and complexes exhibit different colors, geometries, and magnetic behavior, depending on the metal atom/ion and ligands from which they are composed. In an attempt to explain the bonding and structure of coordination complexes, Linus Pauling proposed the valence bond theory, or VBT, using the concepts of hybridization and the overlapping of the atomic orbitals. According to VBT, the central metal atom or ion (Lewis acid) hybridizes to provide empty orbitals of suitable...
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Orbitals are the areas outside of the atomic nucleus where electrons are most likely to reside. They are characterized by different energy levels, shapes, and three-dimensional orientations. The location of electrons is described most generally by a shell or principal energy level, then by a subshell within each shell, and finally, by individual orbitals found within the subshells.
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Updated: Sep 8, 2025

Computation of Atmospheric Concentrations of Molecular Clusters from ab initio Thermochemistry
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リッドバーグ,偽連続体,二極結合軌道を回避しながら,バレンスの抗結合レベルを見つけること

Iwona Anusiewicz1, Piotr Skurski1, Jack Simons2

  • 1Laboratory of Quantum Chemistry, Faculty of Chemistry, University of Gdańsk, Wita Stwosza 63, 80-308 Gdańsk, Poland.

Journal of the American Chemical Society
|June 14, 2022
PubMed
まとめ

この研究は,他の分子軌道からの干渉を克服して,電子構造の計算において,バレンスの抗結合軌道を正確に埋める方法を示している. これは,特にメタステーブルな電子状態の化学プロセスの正確な分析を可能にします.

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科学分野:

  • コンピュータ化学
  • 量子化学について

背景:

  • 化学における実験データの解釈には電子構造法が不可欠である.
  • バレンスの抗結合軌道 (π* と σ*) は,光化学反応,電子還元,および反応動態を理解するために不可欠である.
  • 侵入する軌道 (ライドバーグ,偽連続体,二極結合) は,標的反結合軌道の正確な集団を複雑にすることができます.

研究 の 目的:

  • 電子構造の計算において,バレンスの抗結合軌道を正しく埋めるための実用的な方法を提供する.
  • 類似のエネルギーを持つ分子軌道に 干渉することで生じる課題に対処するためです
  • これらの軌道,特にメタステーブル状態を伴う化学プロセスの正確な計算を可能にします.

主な方法:

  • 広く利用可能な電子構造コードを使用します.
  • 侵入オービタルの影響を回避する戦略を開発する.
  • 高精度な電子相関効果を組み込む.

主要な成果:

  • ヴァレンスの π* と σ* 軌道を埋めるための信頼性の高い手順が示されている.
  • この方法は,干渉軌道によって引き起こされる一般的な落とし穴をうまく回避します.
  • 精密な計算が達成され,化学的に有用な精度,特にメタステーブルな電子状態に提供されます.

結論:

  • 提出されたアプローチは,重要な化学プロセスにおける電子構造計算の信頼性を高めます.
  • 複雑な軌道相互作用がある場合でも,バレンスの抗結合軌道群の正確な数は達成可能である.
  • この方法論は,特に光化学と電子駆動反応において,反応機構とエネルギー景観の研究に価値があります.