New insights into interactions between the core and mantle.
The Earth’s deep interior is difficult to study directly but recent technological advances have enabled new observations, experiments, analysis, and simulations to better understand deep Earth processes.
Core-Mantle Co-Evolution: An Interdisciplinary Approach seeks to address some of the major unsolved issues around the core-mantle interaction and co-evolution. It provides the latest insights into dynamics, structure, and evolution in the core-mantle boundary region.
Volume highlights include:
Latest technological advances in high pressure experiments and their application to understanding the mineral physical properties and stability of phases in deep Earth Recent progress in observational seismology, geochemical analysis, geoneutrino experiments, and numerical modeling for understanding the heterogeneity of the lower mantle Theoretical investigations on thermal-chemical evolution of Earth’s mantle and core Exploring thermal-chemical-mechanical-electromagnetic interactions in the core-mantle boundary regions
The American Geophysical Union promotes discovery in Earth and space science for the benefit of humanity. Its publications disseminate scientific knowledge and provide resources for researchers, students, and professionals.
List of contributors vii Preface ix Part I Structure and Dynamics of the Deep Mantle: Toward Core-Mantle Co-Evolution 1 Neutrino Geoscience: Review, Survey, Future Prospects 3 William F. McDonough and Hiroko Watanabe 2 Trace Element Abundance Modeling with Gamma Distribution for Quantitative Balance Calculations 17 Sanshiro Enomoto, Kenta Ueki, Tsuyoshi Iizuka, Nozomu Takeuchi, Akiko Tanaka, Hiroko Watanabe, and Satoru Haraguchi 3 Seismological Studies of Deep Earth Structure Using Seismic Arrays in East, South, and Southeast Asia, and Oceania 31 Satoru Tanaka and Toshiki Ohtaki 4 Preliminary Results from the New Deformation Multi-Anvil Press at the Photon Factory: Insight into the Creep Strength of Calcium Silicate Perovskite 59 Andrew R. Thomson, Yu Nishihara, Daisuke Yamazaki, Noriyoshi Tsujino, Simon A. Hunt, Yumiko Tsubokawa, Kyoko Matsukage, Takashi Yoshino, Tomoaki Kubo, and David P. Dobson 5 Deciphering Deep Mantle Processes from Isotopic and Highly Siderophile Element Compositions of Mantle-Derived Rocks: Prospects and Limitations 75 Katsuhiko Suzuki, Gen Shimoda, Akira Ishikawa, Tetsu Kogiso, and Norikatsu Akizawa 6 Numerical Examination of the Dynamics of Subducted Crustal Materials with Different Densities 103 Taku Tsuchiya, Takashi Nakagawa, and Kenji Kawai Part II Core-mantle Interaction: An Interdisciplinary Approach 7 SomeIssuesonCore-MantleChemicalInteractions:TheRoleofCoreFormationProcesses 117 Shun-ichiro Karato 8 Heat Flow from the Earth’s Core Inferred from Experimentally Determined Thermal Conductivity of the Deep Lower Mantle 133 Yoshiyuki Okuda and Kenji Ohta 9 Assessment of a Stable Region of Earth’s Core Requiring Magnetic Field Generation over Four Billion Years 145 Takashi Nakagawa, Shin-ichi Takehiro, and Youhei Sasaki 10 Inner Core Anisotropy from Antipodal PKIKP Traveltimes 165 Hrvoje Tkalčić, Thuany P. Costa de Lima, Thanh-Son Phạm, and Satoru Tanaka 11 Recent Progress in High-Pressure Experiments on the Composition of the Core 191 Ryosuke Sinmyo, Yoichi Nakajima, and Yasuhiro Kuwayama 12 Dynamics in Earth’s Core Arising from Thermo-Chemical Interactions with the Mantle 219 Christopher J. Davies and Sam Greenwood Index 259
Takashi Nakagawa, Kobe University and Hiroshima University, Japan Taku Tsuchiya, Ehime University, Japan Madhusoodhan Satish-Kumar, Niigata University, Japan George Helffrich, Tokyo Institute of Technology, Japan
