TY - JOUR
T1 - Simulated molecular-scale interaction of supercritical fluid mobile and stationary phases
AU - Siders, Paul D.
N1 - Publisher Copyright:
© 2017 Elsevier B.V.
PY - 2017/12/8
Y1 - 2017/12/8
N2 - In supercritical fluid chromatography, molecules from the mobile phase adsorb on the stationary phase. Stationary-phase alkylsilane-terminated silica surfaces might adsorb molecules at the silica, among the silanes, on a silane layer, or in pore space between surfaces. Mobile phases of carbon dioxide, pure and modified with methanol, and stationary phases were simulated at the molecular scale. Classical atomistic force fields were used in Gibbs-ensemble hybrid Monte Carlo calculations. Excess adsorption of pure carbon dioxide mobile phase peaked at fluid densities of 0.002–0.003 Å−3. Mobile phase adsorption from 7% methanol in carbon dioxide peaked at lower fluid density. Methanol was preferentially adsorbed from the mixed fluid. Surface silanes prevented direct interaction of fluid-phase molecules with silica. Some adsorbed molecules mixed with tails of bonded silanes; some formed layers above the silanes. Much adsorption occurred by filling the space between surfaces in the stationary-phase model. The distribution in the stationary phase of methanol molecules from a modified fluid phase varied with pressure.
AB - In supercritical fluid chromatography, molecules from the mobile phase adsorb on the stationary phase. Stationary-phase alkylsilane-terminated silica surfaces might adsorb molecules at the silica, among the silanes, on a silane layer, or in pore space between surfaces. Mobile phases of carbon dioxide, pure and modified with methanol, and stationary phases were simulated at the molecular scale. Classical atomistic force fields were used in Gibbs-ensemble hybrid Monte Carlo calculations. Excess adsorption of pure carbon dioxide mobile phase peaked at fluid densities of 0.002–0.003 Å−3. Mobile phase adsorption from 7% methanol in carbon dioxide peaked at lower fluid density. Methanol was preferentially adsorbed from the mixed fluid. Surface silanes prevented direct interaction of fluid-phase molecules with silica. Some adsorbed molecules mixed with tails of bonded silanes; some formed layers above the silanes. Much adsorption occurred by filling the space between surfaces in the stationary-phase model. The distribution in the stationary phase of methanol molecules from a modified fluid phase varied with pressure.
KW - Carbon dioxide adsorption
KW - Excess adsorption
KW - Gibbs ensemble
KW - Methanol modifier
KW - Monte carlo simulation
KW - Supercritical fluid chromatography
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U2 - 10.1016/j.chroma.2017.10.056
DO - 10.1016/j.chroma.2017.10.056
M3 - Article
C2 - 29106964
AN - SCOPUS:85032301148
SN - 0021-9673
VL - 1527
SP - 97
EP - 104
JO - Journal of Chromatography A
JF - Journal of Chromatography A
ER -