Monte Carlo simulations were performed to calculate the temperature dependence of the primary yields
(g-values) of the radical and molecular products of the radiolysis of pure, deaerated liquid water by low
linear-energy-transfer (LET) radiation. The early energy deposition was approximated by considering short
segments (∼100 μm) of 300-MeV proton tracks (corresponding to an average LET of ∼0.3 keV/μm). The
subsequent nonhomogeneous chemical evolution of the reactive species formed in these tracks was simulated
by using the independent reaction times approximation, which has previously been used successfully to model
the radiolysis of liquid water at ambient temperature under various conditions. Our calculated g-values for
the radiolytic species:
, OH, H, H2, and H2O2, are presented as a function of temperature over the range
25−300 °C. They show an increase in g(
), g(OH), and [g(H) + g(H2)] and a decrease in g(H2O2) with
increasing temperature, in agreement with existing experimental data. The sensitivity of the results to the
values of reaction rate constants and to the temperature dependence of electron thermalization distances (r
th)
was also investigated. It was found that the best agreement with experiment occurs when the distances of
electron thermalization decrease with increasing temperature, a result that is at variance with the predictions
of previous modeling studies. Such a decrease in r
th as the temperature increases could be linked to an increase
in the scattering cross sections of subexcitation electrons that would account for the corresponding decrease
in the degree of structural order of water molecules. Our simulations also suggest that the variations of the
g-values with temperature, and especially that of g(H2), are better described if we account for the screening
of the Coulomb forces between the two
in the bimolecular self-reaction of the hydrated electron. Finally,
the time-dependent yields of
and OH are presented as functions of temperature, in the range 10-12−10-6
s. It was found that the temporal variation of g(
) at elevated temperatures is sensitive to the temperature
dependence of r
th, suggesting that measurements of the decay of hydrated electrons as functions of time and
temperature could, in turn, provide information on the thermalization of subexcitation electrons. The good
overall accord of our calculated results with the experimental data available from the literature demonstrates
that Monte Carlo simulation methods offer a most promising avenue at present to further develop our
understanding of temperature effects in the radiolysis of liquid water.
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.