64723-97-3

Upstream product

• 421-50-1 1,1,1-trifluoro-2-propanone 
• 74586-02-0 phenylnitrene anion radical 
• 64480-56-4 2-Methylallyl anion 
• 17302-63-5 methanethiolate 
• 62268-73-9 diphenylcarbene 
• 64723-96-2 acetic acid methyl ester; deprotonated form 
• 64723-93-9 acetaldehyde enolate 
• 62290-59-9 acetic acid ethyl ester; deprotonated form 
• 24262-31-5 acetone enolate ion 

Downstream Products

• 463-51-4 Ketene 
• 75-46-7 trifluoromethan 
• 54128-17-5 trifluoromethanide 
• 41084-91-7 deprotonated ketene anion 
• 421-50-1 1,1,1-trifluoro-2-propanone 
• 65626-52-0 C₄H₄N₃^(1-) 

Relevant academic research and scientific papers

Gas-Phase Broensted versus Lewis Acid-Base Reactions of 6,6-Dimethylfulvene. A Sensitive Probe of the Electronic Structures of Organic Anions

The gas-phase reactions of a series of negative ions with 6,6-dimethylfulvene (DMFU) have been investigated in a flowing afterglow apparatus.Products are formed from competing Broensted and Lewis acid-base reactions wherein the negative ion abstracts a proton from one of the acidic methyl groups, and/or adds to the exocyclic double bond to yield a substituted cyclopentadienide ion.Localized anions such as hydroxide, alkoxides, trifluoromethide, and thiolates react exclusively by proton abstraction, while delocalized ions such as allyl and benzyl yield mainly adduct with somewhat reduced efficiencies.The observed product distributions areindependent of the total pressure in the reactor.Enolate ions show a wide variation in reactivity with DMFU: acyclic aldehyde and ketone enolates react exclusively by proton abstraction, while amide and ester enolates produce mainly adduct, despite their greater thermodynamic basicities.A pronounced ring-size effect is also found with cyclic ketone enolates wherein the larger ring ions such as cyclohexanone enolate show only proton transfer, whereas the small-ring ions such as cyclobutanone enolate show both addition and proton transfer.It is shown that yields for the Broensted and Lewis acid-base reaction products are determined kinetically and that charge delocalization in the negative ion reactant substantially reduces its kinetic basicity.The results forthe ambident enolate ions are shown to be largely determined by the proton affinity differences between the carbon and oxygen ends, i.e., the lower the proton affinity at oxygen, the greater the preference for adduct formation with DMFU through carbon.A detailed mechanism and energy profile is proposed for the DMFU reactions which is based on the results for over 30 different negative ions.Discussion of the relative nucleophilicities and kinetic basicities of these ions is also presented.

Electron transfer as a possible initial step in nucleophilic addition elimination reactions between (radical) anions and carbonyl compounds in the gas phase

The reactions of the HO-, CH3S-, CH2S- and CH2=C(CH3)-CH2- ions with three ketones (CF3COR; R=CH3, CF3, C6H5) and three esters of trifluoroacetic acid (CF3CO2R; R=CH3, C2H5 and C6H5) have been studied with use of Fourier Transform Ion Cyclotron Resonance (FT-ICR) mass spectrometry. All four negative ions react exclusively by proton transfer with CF3COCH3. With the other substrates, the HO- ion reacts by various pathways, such as proton transfer, SN2 substitution, E2 elimination and attack on the carbonyl group. The CH3S- ion is unreactive towards CF3COC6H5 but is able to react by hydride transfer, SN2, E2 and/or carbonyl attack with the remaining neutral species. The CH2S- radical anion reacts by electron transfer to afford stable molecular radical anions of CF3COCF3 and CF3COC6H5, whereas the main reaction with the two esters, CF3CO2CH3 and CF3CO2C2H5, is dissociative electron transfer leading to CF3CO2- and CF3- ions. The CH2=C(CH3)-CH2- anion displays a more complex reactivity pattern involving electron transfer, SN2, E2 as well as attack on the carbonyl group. Direct evidence for the occurrence of electron transfer as the initial step in an overall BAC2 type process has not been obtained for the systems studied. The reaction of the CH2S- ion with CF3CO2C6H5 was observed, however, to yield exclusively a CF3COCHS-. radical anion. Based upon the absence of a BAC2 process in the reaction of CH2S- with the methyl and ethyl esters of trifluoroacetic acid in combination with the facile occurrence of electron transfer from this radical anion, it is suggested that the CF3COCHS-. ion is formed by an initial electron transfer followed by coupling between the CH2S molecule and the CF3CO2C6H5- radical anion and subsequent loss of C6H5OH from the collision complex.

Generation, Thermodynamics, and Chemistry of the Diphenylcarbene Anion Radical (Ph2C.-)

Dissociative electron attachment with Ph2C=N produced Ph2C.- (m/z 166).The reactions of Ph2C.- with potential proton donors of known gas-phase acidity were used to bracket PA(Ph2C.-) = 380 +/- 2 kcal mol-1 from which ΔHf0(Ph2C.-) = 81.8 +/- 2 kcal mol-1 was calculated.The reactions of Ph2C.- with CH3OH and C2H5OH proceeded with major and minor amounts, respectively, of a H2.+-transfer channel, forming Ph2CH2, RCHO, and an electron.The kinetic nucleophilicity of Ph2C.- in SN2 displacement reactions with CH3X and C2H5X molecules was shown to be medium, which requires a significant intrinsic barrier in these reaction.The reactions of Ph2C.- with various aldehydes, ketones, and esters were fast and established two principal product-forming channels: (1) H+ transfer if the neutral reactant contains activated C-H bonds and (2) carbonyl addition followed by radical β-fragmentation of one of the groups originally attached to the carbonyl carbon.The order for the ease of radical β-fragmentation in the tetrahedral intermediates was RO > alkyl >> H, and CO2CH3 > CH3.Since the reactions of Ph2C.- with the simple esters HCO2CH3 and CH3CO2CH3 were fast, it should now be possible to examine the reactions of carbonyl-containing organic molecules, which are expected to react slower than these esters and obtain their relative reactivities.

Gas-Phase Nucleophilic Reactivities of Phenylnitrene (PhN-*) and Sulfur Anion Radicals (S-/.) at sp3 and Carbonyl Carbon

The reactions of PhN-/. with a series of carbonyl-containing molecules (aldehydes, ketones, and esters) were shown to proceed via an addition/fragmentation mechanism, PhN-* + R2C=O -> -)R2> -> PhN=C(O-)R + *R, producing various acyl anilide anion products.In several cases, the tetrahedral intermediate anion radicals were observed as minor ions.The intrinsic reactivity of the carbonyl-containing molecules was aldehydes > ketones > esters, where similar R groups were involved.The overall exothermicities of these reactions did not appear to play the major role in determining the relative rates (krelC=O) for these reactions.From the reaction of PhN-* with cyclobutanone, a new type of anion radical, PhN=C(O-)CH2* (m/z 133) (+ C2H4) was produced; the loss of C2H4 was considered due to the ring strain in the ketone.With cyclopentanone, cyclohexanone, and cycloheptanone, the anion radicals PhN=C(O-)(CH2)n* (n = 4-6) were the exclusive product ions.PhN-* was shown to be a poor nucleophile in SN2 displacement reactions with CH3X molecules (X = Cl, Br, O2CCF3).S-* was shown to exhibit modest SN2 nucleophilicity with CH3Cl and CH3Br.The reactions of S-* with CF3CO2R proceed via both SN2 displacement and carbonyl addition/fragmentation mechanisms: with R = CH3, the anion products were 65percent CF3CO2- and 35percent CF3COS-; from R = C2H5, the product ions were 4percent CF3CO2- and 96percent CF3COS-.These data yield the ratio kCH3/kC2H5 = 16 for SN2 displacement by S-* at these alkyl groups.The reactions of PhN-* with CO2, COS, CS2, and O2 are also reported.The reaction of PhN-* with CS2 to produce S-* as a major channel was used as the source of this atomic anion radical.In several reactions occuring at nearly the collison limit, selectivity was observed for (a) which of two reaction centers were attacked to give products and (b) which of two mechanisms would be dominant in the overall reaction.