Your search keyword '"Heinz, Dion L."' showing total 3 results

1. Chapter 12. HIGH-PRESSURE MELTING OF DEEP MANTLE AND CORE MATERIALS

Author

Shen, Guoyin, primary and Heinz, Dion L., additional

Published

1998

2. High-pressure phase behavior and equations of state of ThO2 polymorphs.

Author

Chidester, Bethany A., Pardo, Olivia S., Fischer, Rebecca A., Thompson, Elizabeth C., Heinz, Dion L., Prescher, Clemens, Prakapenka, Vitali B., and Campbell, Andrew J.

Subjects

EARTH'S mantle, SEISMIC anisotropy, HIGH temperatures, HEAT equation, HIGH pressure (Science)

Abstract

ThO2 is an important material for understanding the heat budget of Earth’s mantle, as well as the stability of nuclear fuels at extreme conditions. We measured the in situ high-pressure, high-temperature phase behavior of ThO2 to ~60 GPa and ~2500 K. It undergoes a transition from the cubic fluorite-type structure (thorianite) to the orthorhombic α-PbCl2 cotunnite-type structure between 20 and 30 GPa at room temperature. Prior to the transition at room temperature, an increase in unit-cell volume is observed, which we interpret as anion sub-lattice disorder or pre-transformation “melting” (Boulfelfel et al. 2006). The thermal equation of state parameters for both thorianite [V0 = 26.379(7), K0 = 204(2), αKT = 0.0035(3)] and the high-pressure cotunnite-type phase [V0 = 24.75(6), K0 = 190(3), αKT = 0.0037(4)] are reported, holding K 0 ′ $\begin{array}{} K_0^{'} \end{array} $ fixed at 4. The similarity of these parameters suggests that the two phases behave similarly within the deep Earth. The lattice parameter ratios for the cotunnite-type phase change significantly with pressure, suggesting a different structure is stable at higher pressure. [ABSTRACT FROM AUTHOR]

Published

2018

3. Equation of state of pyrite to 80 GPa and 2400 K.

Author

THOMPSON, ELIZABETH C., CHIDESTER, BETHANY A., FISCHER, REBECCA A., MYERS, GREGORY I., HEINZ, DION L., PRAKAPENKA, VITALI B., and CAMPBELL, ANDREW J.

Subjects

EQUATIONS of state, SULFUR, X-ray diffraction, COMPRESSION loads, DENSITY

Abstract

The high-cosmic abundance of sulfur is not reflected in the terrestrial crust, implying it is either sequestered in the Earth's interior or was volatilized during accretion. As it has widely been suggested that sulfur could be one of the contributing light elements leading to the density deficit of Earth's core, a robust thermal equation of state of iron sulfide is useful for understanding the evolution and properties of Earth's interior. We performed X-ray diffraction measurements on FeS2 achieving pressures from 15 to 80 GPa and temperatures up to 2400 K using laser-heated diamond-anvil cells. No phase transitions were observed in the pyrite structure over the pressure and temperature ranges investigated. Combining our new P-V-T data with previously published room-temperature compression and thermochemical data, we fit a Debye temperature of 624(14) K and determined a Mie-Grüneisen equation of state for pyrite having bulk modulus KT = 141.2(18) GPa, pressure derivative KT' = 5.56(24), Grüneisen parameter γ0 = 1.41, anharmonic coefficient A2 = 2.53(27) × 10-3 J/(K2·mol), and q = 2.06(27). These findings are compared to previously published equation of state parameters for pyrite from static compression, shock compression, and ab initio studies. This revised equation of state for pyrite is consistent with an outer core density deficit satisfied by 11.4(10) wt% sulfur, yet matching the bulk sound speed of PREM requires an outer core composition of 4.8(19) wt% S. This discrepancy suggests that sulfur alone can-not satisfy both seismological constraints simultaneously and cannot be the only light element within Earth's core, and so the sulfur content needed to satisfy density constraints using our FeS2 equation of state should be considered an upper bound for sulfur in the Earth's core. [ABSTRACT FROM AUTHOR]

Published

2016