Hydrogen–carbon, carbon–carbon double rearrangement induced by proximity effects. Part 3: Essential structural requirements in methoxydiphenylmethanes

Ceraulo̊, Leopoldo; Agozzino, Pasquale; Ferrugia, Mirella; Lamartina, Liliana; Natoli, Maria Concetta

doi:10.1002/oms.1210271024

Cited by 5 publications

(16 citation statements)

References 8 publications

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“…In order to ascertain whether the peak at m/z 91 of 1 and 2 corresponds to the rearrangement ion b (Scheme ), we examined the CI (methane) mass spectra of isotopomers 1d 3 and 2d 3 (Figs 1(b) and 2(b), respectively). The complete shift to m/z 93 confirms the formation of the ion b by the double rearrangement reaction of diphenylmethyl cations, previously observed in electron ionisation mass spectra 1–4. The peaks due to anisole loss, at m/z 107 and 121 for 1 and 2 , respectively, are not shifted in the spectra of the isotopomers 1d 3 and 2d 3 .…”

Section: Resultssupporting

confidence: 86%

“…It has been reported that diphenylmethyl cations formed by the benzylic cleavage of the molecular ions of 1,1‐diphenylalkanes bearing, in the ortho position, an alkoxy, alkyl‐ or dialkylamino or alkylsulfanyl group undergo a double rearrangement process involving consecutively a H‐to‐C migration followed by a C‐to‐C displacement reaction1–4. The overall process affords benzyl (or tropylium) cations through migration of an alkylidene residue of the ortho ‐alkylhetero group to the other aromatic ring (Scheme ), and this constitutes a pathway for benzyl (or tropylium) cation formation not previously reported 5,, 6…”

Section: Methodsmentioning

confidence: 99%

“…This rearrangement has been studied in a series of compounds and it has been determined that the presence of an ortho ‐alkylhetero group alone constitutes the fundamental structural requirement for the occurrence of the reaction 3. The process even occurs for a series of derivatives bearing bulky groups linked to the benzyl carbon.…”

Section: Methodsmentioning

confidence: 99%

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Studies in organic mass spectrometry. Part 25. Benzyl ion formation in chemical ionisation (methane or isobutane) of someortho-alkylhetero-substituted diphenylcarbinols

Bongiorno¹,

Ceraulo̊²,

Lamartina³

et al. 2000

Rapid Commun. Mass Spectrom.

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The behaviour of some ortho-alkylhetero-substituted diphenylcarbinols, including deuterium labelled derivatives, under chemical ionisation (methane or isobutane) conditions has been investigated. It has been determined that ortho-alkylhetero diphenylmethyl cations formed by water elimination from the protonated molecule undergo consecutive rearrangements which afford benzyl (or tropylium) ions previously observed for ortho-substituted diphenylcarbenium ions generated by electron ionisation. This reaction also occurs under low-energy collision conditions. Copyright 2000 John Wiley & Sons, Ltd.

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Section: Resultssupporting

confidence: 86%

Section: Methodsmentioning

confidence: 99%

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Studies in organic mass spectrometry. Part 25. Benzyl ion formation in chemical ionisation (methane or isobutane) of someortho-alkylhetero-substituted diphenylcarbinols

Bongiorno¹,

Ceraulo̊²,

Lamartina³

et al. 2000

Rapid Commun. Mass Spectrom.

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“…2 The isotopic effect indicates that the hydrogen migration affording the rearrangement ion a' is the rate-determining process, and the close values in 70 eV-(k H /k D = 1.4), 1,3 and in MIKE-(k H /k D = 1.6), 2 spectra agree with a loose transition state for the hydrogen migration. 8 In order to achieve detailed mechanistic insight and information on the arrangement of the transition state related to the process involving the hydrogen migration, the determination of substituent effects on the abundance of the benzyl ion formation process could be used as a valuable tool.…”

Section: Methodsmentioning

confidence: 83%

“…2,3 It has been unequivocally demonstrated by experiments with 2 H-and 13 C-labeled compounds that the whole process of benzyl ion formation involves migration of the methylene residue of the methoxy group linked to the 2-position of an aromatic ring (ring A) to the other aromatic ring (ring B). [1][2][3][4] Further investigation revealed that such a reaction occurs also for ortho-alkoxy derivatives (OEt, OiPr) by migration of an alkylidene residue other than methylene, as well as for ortho-alkyl-hetero (NHMe, NMe 2 , SMe) 1,1-diarylalkanes. 4 Finally, it has been determined that the formation of the benzyl-(or tropylium) ions b constitutes the main unimolecular decomposition reaction of ortho-alkylhetero-substituted diaryl-or alkyldiaryl-or triaryl-methyl cations, a, generated either under electron ionization 5 Step 1…”

Section: Introductionmentioning

confidence: 99%

Substituent effects on the formation of benzyl ions from ortho-methoxy substituted 1,1-diarylalkanes under electron ionization: correlations between the abundance of the process and the 13C-NMR chemical shifts of the neutral precursors

Ceraulo̊¹,

Filizzola²,

Fontana³

et al. 2002

Arkivoc

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Good linear relationships have been obtained between the abundance of the formation process of benzyl ions from ortho-methoxy-substituted 1,1-diarylalkanes, through consecutive rearrangement reactions induced by electron ionization, and 13 C-NMR chemical shift values of C-1 of the ortho-methoxy-substituted aromatic ring of the neutral precursors for a large number of compounds: 1,1-diphenylethanes 1-19, 2-methyl-1,1-diphenylpropanes 20-37, and 1,1,1-trichloro-2,2-diphenylethanes 38-44. This result is satisfying as good linear relationships between the ion abundances in the mass spectrum and the substituent effects are not easily obtained. Further, the abundance of the process depends on the effects of substituents linked to the ortho-methoxy-substituted benzene ring (ring A) while measurable effects of substituents linked to the other benzene ring (ring B) have not been observed.

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A novel hydrogen rearrangement of bifunctional o‐xylylene derivatives in chemical ionization mass spectrometry

Nakata

Osogoshi

Noda

et al. 1994

Rapid Comm Mass Spectrometry

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A novel hydrogen rearrangement reaction was found in benzyl ions that have a (benzyl) k -Z C H -group (Z=O or N) at their ortho position. From deuterium labeling experiments, mass analyzed ion kinetic energy spectra with collisional activation, and examination of structure-peak intensity correlation, a mechanism is proposed which involves a direct transfer of hydrogen (hydride) to the structurally remote but spatially close cationic center. The possibility of an alternative, less likely mechanism including an iodneutral complex and/or a proton-bridged complex has also been discussed. I IDuring the course of our recent work on chemical ionization mass spectrometry of bifunctional ~o m p o u n d s ,~-~ we had occasion to measure the chemical ionization mass spectrum of o-[methoxymethyllbenzyl amine (o-CH,0CH2-C6H4--CH2NH2) ( 1)6 and encountered a novel hydrogen rearrangement reaction, which involves a direct transfer of hydrogen (hydride) to the structurally remote but spatially close cationic center. A recent paper by Italian workers' on similar reactions prompted us to report our own results at this stage of the continuing work. EXPERIMENTAL Mass spectraAll mass spectra were measured with either a Shimadzu LKB (Tokyo, Japan) 9000A mass spectrometer/ GCMS-PAC-90 computer system or Shimadzu 9020 D F reversed geometry mass spectrometer with Shimadzu GCMS PAC 1100 S data processing system. The ion source temperature for chemical ionization conditions was 230°C and an accelerating voltage of 3.5 kV was used. The total emission current was 120 pA and the electron energy was 150 eV. Collision-induced dissociation (CID) spectra were obtained by using helium as the collision gas, at a pressure leading to a reduction of the main beam intensity of 30%.

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Hydrogen–carbon, carbon–carbon double rearrangement induced by proximity effects. Part 3: Essential structural requirements in methoxydiphenylmethanes

Cited by 5 publications

References 8 publications

Studies in organic mass spectrometry. Part 25. Benzyl ion formation in chemical ionisation (methane or isobutane) of someortho-alkylhetero-substituted diphenylcarbinols

Studies in organic mass spectrometry. Part 25. Benzyl ion formation in chemical ionisation (methane or isobutane) of someortho-alkylhetero-substituted diphenylcarbinols

Substituent effects on the formation of benzyl ions from ortho-methoxy substituted 1,1-diarylalkanes under electron ionization: correlations between the abundance of the process and the 13C-NMR chemical shifts of the neutral precursors

A novel hydrogen rearrangement of bifunctional o‐xylylene derivatives in chemical ionization mass spectrometry

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