The phase behavior of rhodium (Rh) metal has been studied to 191 GPa and 2700 K using a combination of room-temperature isothermal compression and double-sided flash laser heating experiments. The isothermal compression data have been fitted with a second-order adapted polynomial of order L equation of state (EoS) with best-fitting parameters of
V0=13.764(2)Å3/atom,
K0=258(3)GPa, and
K′=5.36(9). Two-dimensional maps of the uniaxial stress component
t are presented for Rh at different pressures showing the spatial distribution of the local stress state of a relatively high-yield strength material encased in a Bi pressure medium. In addition, a simple, thermal pressure equation-of-state model, based on a single Einstein temperature, has been fitted to the high-pressure-temperature data up to 2700 K at 148 GPa and ambient-pressure thermal expansion data up to 1982 K. Also determined are the best-fitting parameters to reproduce the thermal EoS within the two-dimensional integration software. The optimized parameters are
V0=13.764Å3/atom,
K0=260.54GPa,
K′=5.114,
αT=2.99×10−5 K−1,
∂αT/∂T=1.27×10−9 K−2,
∂K0/∂T=−6.43×10−5GPa/K, and
∂K′/∂T=−9.3×10−10K−1. Published by the American Physical Society 2024