posted on 2022-09-23, 21:43authored byChelsea
L. Price, Ravleen Kaur Kohli, Bilal Shokoor, James F. Davies
The partitioning of semivolatile
organic molecules between
condensed
phases and the vapor phase has broad application across a range of
scientific disciplines, with significant impacts in atmospheric chemistry
for regulating the evolving composition of aerosol particles. Vapor
partitioning depends on the molecular interactions and phase state
of the condensed material and shows a well-established dependence
on temperature. The phase state of solid organic material is not always
well-defined, and many examples can be found for the formation of
amorphous subcooled liquid states rather than crystalline solids.
This can lead to significant changes to vapor equilibrium processes
by modifying the thermodynamics and kinetics of evaporation. Here,
we explore the influence of phase state on the evaporation dynamics
of a series of straight-chain dicarboxylic acids across a range of
above-ambient temperatures. These molecules show an odd/even alteration
in some of their properties based on the number of carbon atoms that
may be connected to their phase state under dry conditions. Using
a newly developed linear-quadrupole electrodynamic balance, we levitate
single particles containing the sample and expose them to dry conditions
across a range of temperatures (ambient to ∼350 K). Using the
rate of evaporation measured from the change in the size or relative
mass, we derive the vapor pressure and enthalpy of vaporization. Light
scattering data allows for unambiguous identification of the phase
of the particles (crystal vs amorphous) allowing the vapor equilibrium
properties to be attributed to a particular state. This work highlights
a new experimental method for characterizing vapor pressures of low
volatility substances and extends the temperature range of available
data for the vapor pressure of terminal dicarboxylic acids. These
measurements show that crystalline and subcooled liquid states persist
at elevated temperatures and provide a direct comparison between subcooled
and crystal phases under the same experimental conditions.