• Bulletin of the Korean Chemical Society
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• 제24권6호
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• pp.829-831
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• 2003

Various theoretical studies of σ-bond activation of organic molecules by transition metal complexes arereviewed. In the homolytic σ-bond activation, the d orbital energy level of the central metal is an importantfactor, as well known. At the same time, the electron-withdrawing substituent which stabilizes the sp3 orbitalaccelerates the homolytic σ-bond activation. In the heterolytic C-H σ-bond activation of RH by $MXL_n$, the XHbond formation is an important driving force, where $MRL_n$ and HX are formed as products. The heterolytic σ-bond activation is also understood in terms of the electrophilic attack of the metal center to the substrate.

• Bulletin of the Korean Chemical Society
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• 제29권10호
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• pp.1920-1926
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• 2008

We investigated the C-H bond activation mechanism of aldimine by the [RhCl$(PPH_3)_3$] model catalyst using DFT B3LYP//SBKJC/6-31G*/6-31G on GAMESS. Due to their potential utility in organic synthesis, C-H bond activation is one of the most active research fields in organic and organometallic chemistry. C-H bond activation by a transition metal catalyst can be classified into two types of mechanisms: direct C-H bond cleavage by the metal catalyst or a multi-step mechanism via a tetrahedral transition state. There are three structural isomers of [RhCl$(PH_3)_2$] coordinated aldimine that differ in the position of chloride with respect to the molecular plane. By comparing activation energies of the overall reaction pathways that the three isomeric structures follow in each mechanism, we found that the C-H bond activation of aldimine by the [RhCl$(PH_3)_3$] catalyst occurs through the tetrahedral intermediate.

• Bulletin of the Korean Chemical Society
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• 제24권8호
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• pp.1059-1060
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• 2003

• Bulletin of the Korean Chemical Society
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• 제10권4호
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• pp.404-406
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• 1989

• Bulletin of the Korean Chemical Society
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• 제10권1호
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• pp.114-116
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• 1989

• Bulletin of the Korean Chemical Society
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• 제25권11호
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• pp.1623-1624
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• 2004

• Bulletin of the Korean Chemical Society
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• 제32권spc8호
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• pp.2865-2866
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• 2011

• 대한화학회지
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• 제8권1호
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• pp.20-24
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• 1964

종합 오비탈을 모형식으로 결합하여 분자 오비탈을 만드는 방법(linear combination of bond orbitals method, LCBO법)을 응용하여 할로겐화메탄($CH_nX_{4-n}$)과 이를 공변하는 원자(혹은 자유기)와의 추출반응(abstraction reaction $CH_nX_{4-n}\;+\;A\;{\to}\;CH_nX_{3-n}\;+\;XA$)에 대한 반응성을 연구하려는 것이 이 논문의 목적이다. 이 반응의 활성화에테르기 ${\eta}$를 계산하려고 다음과 같은 특정을 하였다. $CH_nX_{4-n}$분자가 활성화복합물로 변할때 그의 반응성 결합(reactive bond) C-X에 있는 두 전자는 완전히 이 분자의 타 ${\eta}전자계로부터 분리된다.이런 모델은 자미있는 직감적인 관념을 유인하게 되니 즉 반응성종합과 그의 주위에 있는 화학종합과의 상호작용에 의하여 ${\eta}$전자계의 반응성이 좌우된다는 것이다. 저자들의 이론적계산에 의하면 ${\eta}$는 다음식으로 표시된다. ${\varepsilon}={\zeta}+{\sum}_{i=1}^3{\eta}c-I,$ c-4 (1) Subscript C-i (i=1,2,3)는 C와 원자 i(i=H, Cl, Br, F,${\cdots}$)간의 화학결합을 표시하며 C-4 (4=(4=Cl, Br${\cdots}$) 는 반응성결합을 가르킨다. ${\zeta}$ξ는 상수한 바와 같이 완전분리상태에 있는 C-4종합과 공변원자 A간의 가상적 반응의 활성화에테르기이며 ${\eta}$C-i, C-4는 C-4와 그의 주위결합 C-i간의 상호작용에 의하여 안정화되는 에테르기를 표시한다. 결합강도와 양립하는 ${\eta}$치는 추출하여 (1)식에 대입하면 차식이 유도된다. ${\varepsilon}={\zeta}\;+\;N{\eta}c$-H, C-4 (2) N은 $CH_nX_{4-n}$분자중에 있는 C-4이상의 C-H 및 C-F결합들의 총수이다. 실험치의 를 N에 대하여 도시하면 $CH_nCo_{4-n}\;+\;H\;{\to}\;HCl\;+\;CH_nCl_{3-n},\;CH_nX_{4-n}\;+\;Na\;{\to}\;NaCl\;+\;CH_nCl_{3-n},\;CH_nX_{4-n} \;Na\;{\to}\;NaBr\;+\;CH_nCl_{3-n}$反應系들에 對하여 좋은 直線을 주니 (2)식이 實驗과 一致한다는 것이다

• Bulletin of the Korean Chemical Society
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• 제9권6호
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• pp.388-393
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• 1988

The chemisorption of CO molecules on polycrystalline nickel surface has been studied by investigating the resulting chemisorbed species with the X-ray photoelectron spectroscopy at temperatures between 300K through 433K. It is found that the adsorbed CO molecules are dissociated by the simple C-O bond cleavage as well as by the disproportionation reaction at temperatures above 373K. The former type dissociation is more favored at low coverages and at elevated temperatures. The isotherms of CO chemisorption are obtained from the xps intensities of C 1s peaks, and then the activation energy of the dissociative adsorption is estimated as a function of the CO exposure. These activation energies are extrapolated to zero coverage to obtain the activation energy of chemisorption in which thermal C-O bond cleavage takes place. The value obtained is 38.1 kJ/mol.

• Macromolecular Research
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• 제14권3호
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• pp.354-358
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• 2006

Polybutadiene (BR) was pyrolyzed at $540-860^{\circ}C$ and the effect of pyrolysis temperature on variations in the relative abundance of the major pyrolysis products (C4-, C5-, C6-, C7-, and C8-species) was investigated. Formation of the C4-, C5-, C6-, and C7-species competed with that of the C8-species. Relative intensity of the C8-species decreased with increasing pyrolysis temperature, while that of the C5-, C6-, and C7-species increased. Pyrolysis paths were became more complicated with increasing pyrolysis temperature. We suggested the operation of double bond migration and succeeding rearrangements for the formation of the C5- and C7-species and various rearrangements, including a double bond, for the formation of the C6-species at high temperature. The activation energies for the pyrolysis product ratios of(C5+C6+C7)/C4 and C8/C4 were used to explain the competition reactions to form the pyrolysis products.