Archaeal cyclopentane fragment in a surfactant's hydrophobic tail decreases the Krafft point

Archaea are prokaryotic microorganisms famous for their ability to adapt to extreme environments, including low and high temperatures. Archaeal lipids often are macrocycles with two polar heads and a hydrophobic core that contains methyl groups and in-line cycles. Here we present the design of novel...

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Veröffentlicht in:	Soft matter 2020-02, Vol.16 (5), p.1333-1341
Hauptverfasser:	Mineev, Konstantin S, Volynsky, Pavel E, Galimzyanov, Timur R, Tretiakova, Daria S, Bobrov, Mikhail Y, Alekseeva, Anna S, Boldyrev, Ivan A
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Sprache:	eng
Schlagworte:	Archaea Carboxylic acids Chains Computer simulation Cyclopentane Extreme environments High temperature Hydrophobicity Lipids Low temperature Microorganisms Molecular dynamics Pollutants Surfactants
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creator	Mineev, Konstantin S Volynsky, Pavel E Galimzyanov, Timur R Tretiakova, Daria S Bobrov, Mikhail Y Alekseeva, Anna S Boldyrev, Ivan A
description	Archaea are prokaryotic microorganisms famous for their ability to adapt to extreme environments, including low and high temperatures. Archaeal lipids often are macrocycles with two polar heads and a hydrophobic core that contains methyl groups and in-line cycles. Here we present the design of novel general-purpose surfactants that have inherited features of archaeal lipids. These are C12 and C14 carboxylic acids containing in-line cyclopentanes. The cyclopentanes disturb the chain packing, which results in remarkable expansion of the operational range of the surfactant into the low-temperature region. We report synthesis and properties of these novel archaea-like surfactants and details of their chain packing derived from thermodynamics model predictions, molecular dynamics simulations, and experimental data on CMC and Krafft points. Cyclopentane fragment in the hydrophobic tail expands operational range of the surfactant into the low-temperature region.
doi_str_mv	10.1039/c9sm02000d
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source	Royal Society Of Chemistry Journals 2008-; Alma/SFX Local Collection
subjects	Archaea Carboxylic acids Chains Computer simulation Cyclopentane Extreme environments High temperature Hydrophobicity Lipids Low temperature Microorganisms Molecular dynamics Pollutants Surfactants
title	Archaeal cyclopentane fragment in a surfactant's hydrophobic tail decreases the Krafft point
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