Effect of chain length on the rate of quaternization of alkyl amines

Friedli, F. E.

doi:10.1007/bf02638964

Cited by 7 publications

(9 citation statements)

References 24 publications

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“…The energies of activation (also in Table II) calculated from the slopes for the three reactions were identical within the uncertainties of the measurements. This is consistent with Friedli's observation [16] that alkylation rates of tertiary amines are independent of carbon chain length when alkyl chains are longer than three carbons. The H ‡ and S ‡ values (Table III) for the same three reactions determined from the Eyring equation (Eq.…”

Section: Resultssupporting

confidence: 92%

Kinetic study of the reaction of dimethyl carbonate with trialkylamines

Weisshaar

Earl

Villa

et al. 2010

Int J of Chemical Kinetics

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Quaternary ammonium compounds are produced worldwide in hundreds of millions of pound volume annually for a plethora of end-uses from fabric-care formulations to asphalt emulsifiers, typically from nongreen alkylating reagents. The kinetics of a reaction employing dimethyl carbonate (DMC) as a green alkylating agent was investigated using three trialkylamines (tributylamine, trihexylamine, and trioctylamine) at several temperatures. Arrhenius and Eyring analysis of the data showed that values of E a (79 kJ/mol), H ‡ (75 kJ/mol), and S ‡ (220 J/(mol K)) were the same for all three amine reactants, consistent with a report that E a is independent of alkyl chain length when the chain length is greater than three carbons. Although rates are significantly slower with DMC than with other alkylating reagents, the resulting methyl carbonate anion has advantages for clean anion metathesis, which is important for some applications, especially those involving ionic liquids. C

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Section: Resultssupporting

confidence: 92%

Kinetic study of the reaction of dimethyl carbonate with trialkylamines

Weisshaar

Earl

Villa

et al. 2010

Int J of Chemical Kinetics

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“…In contrast to this, the reactivity of those bis(2‐N,N‐dialkylamino)ethyl ether compounds was lower compared to bis[2‐(N,N)‐dimethylamino]ethyl ether in the conducted poly‐Menshutkin‐reactions with alkyl dibromides, since lower yields were obtained. This can be deduced to a deleterious steric effect of the alkyl substituents and a less efficient nucleophilic performance 36. Nevertheless, both monomers reacted at room temperature to form oligomers, as proven by mass spectrometry.…”

Section: Resultsmentioning

confidence: 99%

Closing One of the Last Gaps in Polyionene Compositions: Alkyloxyethylammonium Ionenes as Fast‐Acting Biocides

Mattheis¹,

Zheng²,

Agarwal³

2011

Macromolecular Bioscience

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Alkyloxyethylammonium ionenes are reported as biocompatible biocides with a time of biocidal action within a few minutes. The presence of both ethoxyethyl and aliphatic spacers besides long alkyl chain substituents on the quaternary nitrogen atom differentiates these biocides structurally from the known polyionenes. The influence of alkyl spacer length, counter ion and length of the pendant alkyl groups on the antibacterial properties is studied. E. coli is adopted as a test organism. MIC and MBC values are determined via broth dilution methods; time-dependent tests are accomplished by determining the number of viable cells with the spread-plate method after different contact times. Structural characterization is conducted via NMR and mass spectrometry techniques.

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“…in 1990 19 . The described trends apply both at 120 and 200 • C. It is peculiar that the effect of chain length (TDMA-MC vs. TBMA-MC) seems to be reversed at 200 • C in DMC.…”

Section: Degradation Kineticsmentioning

confidence: 99%

Degradation Kinetics and Solvent Effects of Various Long-Chain Quaternary Ammonium Salts

Kleijwegt

Winkenwerder

Baan³

et al. 2021

Preprint

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<div>Surfactants such as quaternary ammonium salts (QAS) have been in increasing demand, for emerging new applications. Recent attempts at process intensification of</div><div>their production, have disclosed the need for a better understanding of QAS thermal stability. This work aims to determine degradation kinetics of various QASs, and the</div><div>associated solvent effects. Degradation kinetics of four methyl carbonate QASs were determined in various</div><div>polar solvents in stainless steel batch autoclaves. <sup>1</sup>H NMR spectrometry was employed for online analysis of the reaction mixtures. The kinetic parameters were then used</div><div>to compare the thermal stability of the four compounds in the polar solvents. Water showed not degradation, and methanol (MeOH) was the solvent that provided the</div><div>second-best stability. Water-MeOH mixtures may provide an overall optimum. More, and longer long-chain substituents increased the degradation rate. Thermogravimetric Analysis was used to obtain the thermal stability in a solid-</div><div>state, i.e. solventless environment. Isoconversional analysis showed that no reliable kinetic parameters could be determined. Nevertheless, the data did allow for a compar-</div><div>ison of the thermal stability of 14 different QASs. Furthermore, the relative instability of the compounds in solid-state demonstrated the challenges of solventless QAS production.</div>

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Effect of chain length on the rate of quaternization of alkyl amines

Cited by 7 publications

References 24 publications

Kinetic study of the reaction of dimethyl carbonate with trialkylamines

Kinetic study of the reaction of dimethyl carbonate with trialkylamines

Closing One of the Last Gaps in Polyionene Compositions: Alkyloxyethylammonium Ionenes as Fast‐Acting Biocides

Degradation Kinetics and Solvent Effects of Various Long-Chain Quaternary Ammonium Salts

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