Primary Convener:
Sibo Chen, Arizona State University

Convener:
Ian Szumila, Carnegie Institution for Science
Joseph Gonzalez, University of South Florida

Chair:
Sibo Chen, Arizona State University
Ian Szumila, Carnegie Institution for Science
Joseph Gonzalez, University of South Florida

Understanding the behavior of Earth and planetary materials under extreme conditions often requires more than a single method. Recent progress in various experimental methods, such as large-volume press, diamond anvil cell, and dynamic compression, have provided new opportunities to study how materials behave under high pressure and temperature. Modern density functional theory and molecular dynamics, enhanced by machine learning, now enable realistic length and time scale simulations of complex phenomena with quantum accuracy. Integrating static, dynamic, and computational methods provides a clearer understanding of phase changes, elastic properties, and transport behaviors of materials in the interiors of Earth and super-Earth exoplanets. This session invites contributions that combine different high-pressure experimental and computational methods, discuss challenges in these approaches, and demonstrate how multi-method studies advance research in mineral and rock physics for planetary interiors. Studies that combine two or more experimental and computational methods are particularly encouraged.

Index Terms
3924 High-pressure behavior
3944 Shock wave experiments
3994 Instruments and techniques

Cross-Listed:
P - Planetary Sciences
DI - Study of the Earth´s Deep Interior

GeoBurst Sessions:
Yes

Neighborhoods:
2. Earth Interior