1146-65-2Relevant articles and documents
ISOTOPE EFFECTS IN AROMATIZATION OF 1,4-DIHYDROBENZENE AND 1,4-DIHYDRONPHTHALENE WITH QUINONES
Mueller, P.,Joly, D.
, p. 3033 - 3036 (1980)
Aromatization of 1,4-dihydronaphthalene with 2,3-dichloro-5,6-p-benzoquinone or chloranil is accompanied with kinetic isotope effects of 9.9 and 8.0 respectively.
Evidence for Concerted Transfer of Hydrogen from Tetralin to Coal Based on Kinetic Isotope Effects
Brower, K.R.,Pajak, Janusz
, p. 3970 - 3973 (1984)
The H/D kinetic isotope effects for the reaction of subbituminous coal with tetralin-d12, tetralin-1,1,4,4-d4, and tetralin-2,2,3,3-d4 are respectively 3.7, 2.0, and 2.0.This pattern is consistent with concerted transfer of a pair of hydrogen atoms from the 1- and 2-positions.It does not result from exchange of hydrogen in unreacted tetralin and is difficult to explain as an anomalous secondary effect.The H/D kinetic isotope effects for 1,2-dihydronaphthalene-d10 and -1,1,3-d3 are 2.7 and 1.1.The latter appears to be a typical secondary effect.The rate determining step is thought to be transfer of a single hydrogen from the 2-position, probably as hydride ion.The activation volume for 1,2-dihydronaphthalene is -23mL mol.This result is consistent with the proposed mechanism or almost any other bimolecular mechanism.
Arene-mercury complexes stabilized by gallium chloride: Relative rates of H/D and arene exchange
Branch, Catherine S.,Barron, Andrew R.
, p. 14156 - 14161 (2002)
We have previously proposed that the Hg(arene)2(GaCl4)2 catalyzed H/D exchange reaction of C6D6 with arenes occurs via an electrophilic aromatic substitution reaction in which the coordinated arene protonates the C6D6. To investigate this mechanism, the kinetics of the Hg(C6H5Me)2(GaCl4)2 catalyzed H/D exchange reaction of C6D6 with naphthalene has been studied. Separate second-order rate constants were determined for the 1- and 2-positions on naphthalene; that is, the initial rate of H/D exchange = k1i[Hg][C-H1] - k2i[Hg][C-H2]. The ratio of k1i/k2 ranges from 11 to 2.5 over the temperature range studied, commensurate with the proposed electrophilic aromatic substitution reaction. Observation of the reactions over an extended time period shows that the rates change with time, until they again reach a new and constant second-order kinetics regime. The overall form of the rate equation is unchanged: final rate = k1f[Hg][C-H1] + k2f[Hg][C-H2]. This change in the H/D exchange is accompanied by ligand exchange between Hg(C6D6)2(GaCl4)2 and naphthalene to give Hg(C10H8)2(GaCl4)2, that has been characterized by 13C CPMAS NMR and UV-visible spectroscopy. The activation parameters for the ligand exchange may be determined and are indicative of a dissociative reaction and are consistent with our previously calculated bond dissociation for Hg(C6H6)2(AlCl4)2. The initial Hg(arene)2(GaCl4)2 catalyzed reaction of naphthalene with C6D6 involves the deuteration of naphthalene by coordinated C6D6; however, as ligand exchange progresses, the pathway for H/D exchange changes to where the protonation of C6D6 by coordinated naphthalene dominates. The site selectivity for the H/D exchange is initially due to the electrophilic aromatic substitution of naphthalene. As ligand exchange occurs, this selectivity is controlled by the activation of the naphthalene C - H bonds by mercury.
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Goubeau et al.
, p. 214,226 (1953)
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METHOD FOR PREPARING DEUTERATED ORGARNIC COMPOUNDS AND DEUTERATED ORGARNIC COMPOUNDS PRODUCED BY THE SAME
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Paragraph 0202-0205, (2019/08/21)
The present invention relates to a manufacturing method of a deuterated organic compound and a deuterated organic compound manufactured thereby. According to the manufacturing method of a deuterated organic compound, it is possible to provide a deuterated organic compound having an excellent deuterium conversion ratio. In addition, by using an aliphatic hydrocarbon solvent having 7 or more carbon atoms, it is possible to increase solubility of an organic compound, thereby increasing the deuterium conversion ratio.COPYRIGHT KIPO 2019
Equatorial preference in the C-H activation of cycloalkanes: GaCl 3-catalyzed aromatic alkylation reaction
Yonehara, Fumi,Kido, Yoshiyuki,Sugimoto, Hiraku,Morita, Satoshi,Yamaguchi, Masahiko
, p. 6752 - 6759 (2007/10/03)
GaCl3 catalyzes the aromatic alkylation of naphthalene or phenanthrene using cycloalkanes. The C-C bond formation predominantly takes place at the least hindered positions of the substrates, and equatorial isomers regarding the cycloalkane moiety are generally obtained. The reaction of bicyclo[4.4.0]decane and naphthalene occurs at the 2-position of naphthalene and at the 2- or 3-carbons of the cycloalkane, and the products possess a trans configuration at the junctures and an equatorial configuration at the naphthyl groups. Notably, cis-bicyclo[4.4.0]decane turns out to be much more reactive than the trans isomer, and a turnover number "TON" up to 20 based on GaCl3 is attained. 1,2-Dimethylcyclohexane reacts similarly, and the cis isomer is more reactive than the trans isomer. Monoalkylcycloalkanes react at the secondary carbons provided that the alkyl group is smaller than tert-butyl. Adamantanes react at the tertiary 1-position. The alkylation reaction is considered to involve the C-H activation of cycloalkanes with GaCl3 at the tertiary center followed by the migration of carbocations and electrophilic aromatic substitution yielding thermodynamically stable products. The stereochemistry of the reaction reveals that GaCl 3 activates the equatorial tertiary C-H bond rather than the axial tertiary C-H bond.