Henry's law coefficients and partial molar volumes of 34 penetrants (5 inert gases, 6
inorganic gases, 17 hydrocarbon gases, 5 fluorinated gases, and CCl4 vapor) dissolved in poly(dimethylsiloxane) and low-density polyethylene were determined at 25 °C by measuring sorption of the
gases and the concomitant dilation of the polymers. From the Henry's law coefficients and the partial
molar volumes, Flory−Huggins parameters for polymer/gas interactions were estimated. The partial molar
volumes were correlated with critical molar volumes of gases, and the interaction parameters were found
to depend on the partial molar volumes. These relationships for the fluorinated gases were clearly different
from those of all other gases. For CO2 and CH4 in poly(dimethylsiloxane), partial molar volumes and
interaction parameters were obtained as a function of temperature over a range −30 to 95 °C. Thermal
expansivities of these dissolved molecules were estimated to be 2 × 10-3 °C-1 from the temperature
dependence of partial molar volumes.
Sorption of CO2 in poly(methyl
methacrylate) at 35−200 °C and concurrent dilation of
the
polymer at 35−85 °C over a pressure range up to 50 atm were
studied. Dissolution and Flory−Huggins
interaction parameters for the gas in the polymer, not only in the
rubbery state but also in the glassy
state, were estimated by analyzing the sorption data above the glass
transition temperature (T
g0, 105
°C). Isothermal glass transition of the polymer/gas system was
observed on isotherms of sorption and
dilation below T
g0. Partial molar volumes
of sorbed CO2 determined from the sorption and
dilation
isotherms increased with increasing concentration to the glass
transition concentration. These isotherms
were also analyzed on the basis of extended dual-mode models of
sorption and dilation. From obtained
parameters of the dual-mode models, nonequilibrium properties such as
mean size and number of
microvoids for the pure polymer and the CO2-sorbed polymer
in the glassy state were evaluated. The
mean size, dependent upon CO2 exposure history of the
polymer, was in the range of 20−100 A3, and
the
number of microvoid ((1−18) × 1020
voids/cm3) was dependent upon both temperature and the
exposure
history.
Sorption and dilation in the system poly(ethyl methacrylate) (PEMA) and carbon dioxide are reported for pressures up to 50 atm over the temperature range 15–85°C. The sorption isotherms were obtained gravimetrically. The dilation accompanying sorption was measured directly with a cathetometer. At low temperatures the sorption and dilation isotherms were concave toward the pressure axis in the low‐pressure region and turned to convex with increasing pressure. As the experimental temperature approached and exceeded the glass transition temperature of 61°C, both isotherms became convex or linear over the whole range of pressure. Partial molar volumes of CO2 in PEMA were obtained from sorption and dilation data, which were described well by the extended dual‐mode sorption and dilation models developed recently. The temperature dependence of the dual‐mode parameters and the isothermal glass transition are discussed.
A gravimetric method for determining precisely the solubility of gases in polymers at high pressure is described. The solubilities of N2 and CO2 in low‐density polyethylene (LDPE); CO2 in polycarbonate (PC); and N2, CH4, C2H6, and CO2 in polysulfone (PSUL) have been measured as a function of pressure up to 50 atm. Most of the measured sorption isotherms agreed closely with published data, but reproducible and time‐dependent hysteresis in the sorption of CO2, C2H6, and CH4 in glassy polymers, PC, and PSUL, was observed in this study for the first time. Like the well known conditioning effect of high‐pressure CO2 on the sorption capacity of glassy polymers, these hysteresis phenomena are believed to be due to the plasticizing effect of sorbed gases. On the basis of the current data, the dual‐mode sorption model including the plasticization by sorbed gas is discussed and a primitive equation for the concentration of sorbed gases in a quasiequilibrium state of sorption or desorption is proposed.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.