北京高压科学研究中心
Center for High Pressure Science &Technology Advanced Research

Dr. Shenghua Mei[Institute of Deep Sea Science and Engineering, Chinese Academy of Sciences]

Dr. Shenghua Mei [Institute of Deep Sea Science and Engineering, Chinese Academy of Sciences]

Title: Experimental study on mantle rheology
Time: 10:00 - 11:00 AM, Friday, May 14, 2021Place: Conference room A417, HPSTAR (Beijing)

Tencent meeting: https://meeting.tencent.com/s/3aqMy7S4KY9n , Meeting ID: 418 162 521

Host: Qingyang Hu

Abstract:

There is water in mantle rocks, which in turn affects mantle rocks. Under the extreme conditions of mantle temperature

and pressure, even if there is a trace of water, it will have a strong impact on the physical, chemical and mechanical

properties of mantle rocks. By carrying out experimental study, the effects of water on the rheological properties of

the main constituent minerals of the mantle(such as olivine, enstatite, and garnet) have been systematically investigated;

which provide the necessary experimental constraints for defining the rheological properties of the mantle.

Biography of the Speaker:

Shenghua Mei, PhDInstitute of Deep Sea Science andEngineering, Chinese Academy of Sciences Address:

Luhuitou Rd 28, Sanya 572000,Hainan Province, P. R. China

Tel: 0898-88210277 Email: mei@idsse.ac.cn

Biography of the Speaker:

Shenghua Mei, PhD

Institute of Deep Sea Science andEngineering, Chinese Academy of Sciences

Address: Luhuitou Rd 28, Sanya 572000,Hainan Province, P. R. China

Tel: 0898-88210277 Email: mei@idsse.ac.cn

· Education

B.S., Geophysics, 1983, Universityof Science and Technology of China

M.S., Geodynamics, 1986, Graduate School, Chinese Academy of Sciences

Ph.D., Materials Sciences, 1999, University of Minnesota

· Professional Experience

2000–2001, University of Minnesota

Post-doc, Dept. of Geology and Geophysics

2002- 2004, Lawrence Livermore National Laboratory

Post-doc Research Scientist, Earth Sciences Department

2005–2016, University of Minnesota

Senior Research Associate, Dept. of Geosciences

2017 – Present, Institute of Deep Sea Science and Engineering, Chinese Academy of Sciences

Senior Research Associate, Lab for Experimental Study under Extreme Conditions

Adjunct professor, University of Minnesota

· Professional honors and activities

Associate Secretary General (1987 - 1991), Chinese Society of Rock Mechanics

Member, Steering committee (2007–2010), Physical Properties of Earth Materials, American Geophysical Union

Member (2017 – present), Committee for Experimental Geochemistry, China

Associate Director (2020 – present), High temperature and high pressure Rock Mechanics Committee, China

Director (2017 – present), Key Lab for Experimental Study under Deep-sea Extreme Conditions, Chinese Academy of Sciences

In 2017, selected into the academic talent program, Chinese Academy of Sciences.

· Research Interests

My research focuses on physical and chemical behavior of minerals and rocks at high pressures and temperatures,

with particular emphasis on kinetic properties. In specific, we investigate the influence of thermodynamic parameters

(e.g., pressure and temperature) and chemical environment (e.g., water and melt) on the rheological properties of

mantle rocks. Motivation for our experiments derives from the importance of quantifying the behavior of geological

materials under extreme conditions as the basis for understanding and modeling the dynamical behavior and

chemical evolution of deep interiors of terrestrial planets.

· Publications and achievements

Published more than 70 articles (omitted);
A number of innovative achievements have been made in high temperature rheology, low temperature plasticity,

melting effect, element diffusion and so on; in the field of mineral physics and chemistry.

Through the experimental study, a series of flow laws of mantle minerals have been established;

which are widely used in the field of geodynamics (a single work has been cited more than 1000 times).

Our research work provides sufficient experimental constraints for understanding the dynamic processes occurring

within the earth’s interior.