105 research outputs found
Solution of the spherically symmetric linear thermoviscoelastic problem in the inertia-free limit
The coupling between mechanical and thermal properties due to thermal
expansion complicates the problem of measuring frequency-dependent
thermoviscoelastic properties, in particular for highly viscous liquids. A
simplification arises if there is spherical symmetry where - as detailed in the
present paper - the thermoviscoelastic problem may be solved analytically in
the inertia-free limit, i.e., the limit where the sample is much smaller than
the wavelength of sound waves at the frequencies of interest. As for the
one-dimensional thermoviscoelastic problem [Christensen et al., Phys. Rev. E
75, 041502 (2007)], the solution is conveniently formulated in terms of the
so-called transfer matrix, which directly links to the boundary conditions that
can be experimentally controlled. Once the transfer matrix has been calculated,
it is fairly easy to deduce the equations describing various experimentally
relevant special cases (boundary conditions that are adiabatic, isothermal,
isochoric, etc.). In most situations the relevant frequency-dependent specific
heat is the longitudinal specific heat, a quantity that is in between the
isochoric and isobaric frequency-dependent specific heats
Frequency Dependent Specific Heat from Thermal Effusion in Spherical Geometry
We present a novel method of measuring the frequency dependent specific heat
at the glass transition applied to 5-polyphenyl-4-ether. The method employs
thermal waves effusing radially out from the surface of a spherical thermistor
that acts as both a heat generator and thermometer. It is a merit of the method
compared to planar effusion methods that the influence of the mechanical
boundary conditions are analytically known. This implies that it is the
longitudinal rather than the isobaric specific heat that is measured. As
another merit the thermal conductivity and specific heat can be found
independently. The method has highest sensitivity at a frequency where the
thermal diffusion length is comparable to the radius of the heat generator.
This limits in practise the frequency range to 2-3 decades. An account of the
3omega-technique used including higher order terms in the temperature
dependency of the thermistor and in the power generated is furthermore given.Comment: 17 pages, 15 figures, Substantially revised versio
Investigation of the shear-mechanical and dielectric relaxation processes in two mono-alcohols close to the glass transition
Shear-mechanical and dielectric measurements on the two monohydroxy
(mono-alcohol) molecular glass formers 2-ethyl-1-hexanol and 2-butanol close to
the glass transition temperature are presented. The shear-mechanical data are
obtained using the piezoelectric shear-modulus gauge method covering
frequencies from 1mHz to 10kHz. The shear-mechanical relaxation spectra show
two processes, which follow the typical scenario of a structural (alpha)
relaxation and an additional (Johari-Goldstein) beta relaxation. The dielectric
relaxation spectra are dominated by a Debye-type peak with an additional
non-Debye peak visible. This Debye-type relaxation is a common feature peculiar
to mono-alcohols. The time scale of the non-Debye dielectric relaxation process
is shown to correspond to the mechanical structural (alpha) relaxation.
Glass-transition temperatures and fragilities are reported based on the
mechanical alpha relaxation and the dielectric Debye-type process, showing that
the two glass-transition temperatures differ by approximately 10K and that the
fragility based on the Debye-type process is a factor of two smaller than the
structural fragility. If a mechanical signature of the Debye-type relaxation
exists in these liquids, its relaxation strength is at most 1% and 3% of the
full relaxation strength of 2-butanol and 2-ethyl-1-hexanol respectively. These
findings support the notion that it is the non-Debye dielectric relaxation
process that corresponds to the structural alpha relaxation in the liquid.Comment: 8 pages, 6 figures. Minor corrections, updated figures, more
dielectric data show
Dynamic thermal expansivity of liquids near the glass transition
Based on previous works on polymers by Bauer et al. [Phys, Rev. B (2000)],
this paper describes a capacitative method for measuring the dynamical
expansion coefficient of a viscous liquid. Data are presented for the
glass-forming liquid tetramethyl tetraphenyl trisiloxane (DC704) in the
ultraviscous regime. Compared to the method of Bauer et al. the dynamical range
has been extended by making time-domain experiments and by making very small
and fast temperature steps. The modelling of the experiment presented in this
paper includes the situation where the capacitor is not full because the liquid
contracts when cooling from room temperature down to around the
glass-transition temperature, which is relevant when measuring on a molecular
liquid rather than polymer
Identical temperature dependence of the time scales of several linear-response functions of two glass-forming liquids
The frequency-dependent dielectric constant, shear and adiabatic bulk moduli,
longitudinal thermal expansion coefficient, and longitudinal specific heat have
been measured for two van der Waals glass-forming liquids,
tetramethyl-tetraphenyl-trisiloxane (DC704) and 5-polyphenyl-4-ether. Within
the experimental uncertainties the loss-peak frequencies of the measured
response functions have identical temperature dependence over a range of
temperatures, for which the Maxwell relaxation time varies more than nine
orders of magnitude. The time scales are ordered from fastest to slowest as
follows: Shear modulus, adiabatic bulk modulus, dielectric constant,
longitudinal thermal expansion coefficient, longitudinal specific heat. The
ordering is discussed in light of the recent conjecture that van der Waals
liquids are strongly correlating, i.e., approximate single-parameter liquids.Comment: 8 pages, 6 figures, Substantially revised versio
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