Geothermal
energy offers the potential to provide continuous baseload
renewable energy. Unlike conventional geothermal approaches, emerging
closed-loop geothermal can employ specialized fluids that improve
thermal energy recovery and expand the range of applications. However,
the requirements for candidate fluids are challenging. The fluids
must be physically and chemically stable under high-temperature, -pressure,
and -shear conditions. Their effective heat capacity must be high
and their viscosity must also be low, factors that motivated us to
use a high-latent heat phase change material within a low-viscosity
carrying fluid. Here, we prepare the microencapsulated phase change
material-based slurries (PCSs) and perform a comprehensive thermal
and hydrodynamic characterization to assess their suitability for
use in a closed-loop geothermal operation. The thermophysical properties
of the PCSs show promising results with minimal change in onset temperature
(2.14 °C) and low supercooling (2.21 °C) during charging
and discharging, respectively. A suitably low viscosity (in the range
0.01–0.05
Pa·s at 300 s–1) could be obtained with PCS
concentrations in the range 20–30 wt %. Higher concentrations
resulted in higher viscosities that would incur pumping energy costs
exceeding the potential thermal storage benefits. At 30 wt % PCM,
this fluid offers the potential for approximately 30% more stored
energy than water alone for the 80 °C system. With respect to
robustness under combined thermal and shear stresses, a PCS with 30
wt % phase change material showed no visible separation ratio and
no shell rupturing or chemical changes when cycled 10× from
20 to 80 °C while being sheared at operation-relevant rates of
10–300 s–1. This study delineates and de-risks
PCSs as geo-fluids, exploiting both sensible and latent heat storage
with physical and chemical stability.