C. A. Herbst scite author profile

The pressure and temperature dependent viscosities of two glass forming liquids, glycerol and dibutyl phthalate (DBP), have been studied in the range P=0–3 GPa, T=0–125 °C, and η=101–1010 cP. These studies were made using a combination of a rolling-ball and a centrifugal-force diamond anvil cell viscometer. The majority of the results extend up to viscosities of 107 cP, with those at 22.5 °C going to 1010 cP. The overall precision of the data are approximately 10% or better throughout. This level of precision allows us to define a viscosity surface which can then be extrapolated to the glass transition along both temperature and pressure cuts. The T-dependence of viscosity is larger for glycerol than DBP but the P-dependence smaller for glycerol than for DBP, whereas the T-dependence is much more pressure sensitive for DBP. These data provide an assessment of the T-dependence of an isothermal model (free volume), the P-dependence of an isobaric model (Vogel–Tammann–Fulcher) and by extension that for isochoric conditions. Fragility parameters are evaluated for these three isometric conditions. For glycerol and (less conclusively) DBP under isobaric conditions, the fragility increases markedly at high pressure. Under isochoric conditions, the fragility for both glycerol and DBP increases with increasing density. This is dramatic for DBP, which goes from a strong to an intermediate-strength liquid. For the isothermal model, we derive a new measure of fragility. Using this, DBP shows a trend common to several liquids, a decrease in fragility with increasing temperature. Glycerol, however, becomes more fragile over the same temperature range. For glycerol, the trends towards increased fragility at elevated pressure and temperature are consistent with diminished hydrogen bonding under those conditions. The P-dependence of the glass transition is also determined over a wide range of T. The slope, dTg/dP, is positive with the pressure dependence for glycerol being considerably smaller than for DBP; both are nonlinear, tending to saturate in temperature at high pressures.

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High-pressure viscosity of glass-forming liquids measured by the centrifugal force diamond anvil cell viscometer

Cook¹,

Herbst²,

King³

1993

J. Phys. Chem.

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High-pressure viscosity of glycerol measured by centrifugal-force viscometry

Herbst

Cook

King

1993

Nature

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Density-mediated transport and the glass transition: high pressure viscosity measurements in the diamond anvil cell

Herbst

Cook

King

1994

Journal of Non-Crystalline Solids

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High-pressure viscoelastic properties and equation of state of liquids derived from Brillouin data

et al. 1991

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Brillouin scattering in an organic glass-forming liquid up to a pressure of 12 GPa is reported. The onset of the unrelaxed regime is indicated by a distinct maximum in the acoustic attenuation at a pressure P a , above which weak shear modes are resolved. Sound velocity data are fitted in a self-consistent way which accounts for relaxation by combining the "universal" Vinet equation of state with an expression for the dynamical modulus. This analysis yields the pressure dependences of the relaxed and unrelaxed moduli, relaxation time, and density over the pressure range studied.

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C. A. Herbst

Pressure and temperature dependent viscosity of two glass forming liquids: Glycerol and dibutyl phthalate

High-pressure viscosity of glass-forming liquids measured by the centrifugal force diamond anvil cell viscometer

High-pressure viscosity of glycerol measured by centrifugal-force viscometry

Density-mediated transport and the glass transition: high pressure viscosity measurements in the diamond anvil cell

High-pressure viscoelastic properties and equation of state of liquids derived from Brillouin data

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