Mineral Physics: Comparison
Please note this is a comparison between Version 1 by Robert Cooper Liebermann and Version 3 by Catherine Yang.

Mineral physics is the study of mineralogical problems through the application of condensed matter physics and solid-state chemistry.  

  • mineral physics
  • ultrasonic interferometry
  • sound velocities
  • high pressure
  • high temperature

1. Introduction1. Introduction

 

 

2. Section 2 Name

The first sAcientific conference focused on mineral physics was held at the Airlie House in Warrenton, Virginia in October 1977. In the ensuing years, many other meetings were convened, dedicated journals were founded, national programs were established, all of which marked the emergence of the discipline of minecording to Robert Hazen [1], “mineral physics into the mainstream of geosciences. At the onset of the 21st century, s the study of mineral physicists found themselves with many challengingogical problems and many exciting opportunities for research at high pressures and temperatures, made possible in large measure to access to synchrotron radiation facilities throughout the world. In this paper, we highlight this evolution of the field of through the application of condensed matter physics”. In reality, mineral physics over this period [1]

2. History and Evolution of Mineral Physics

Althoists ugh many investigators worked on problems related to minerale not only physics during the latter half of the 19th century and the early 20th century [e.g, Erskine Williamson at the Geophysical Laboratory of the Carnegie Institution of Washington, two outstanding contributors were from Harvard University. Percy Bridgman became a Harvard professor in 1919 and devoted his entire scientific career to investigating the properties of matter under high pressure. His opposed-anvil apparatus enabled him to achieve pressures up to 10 GPa and led to important discoveriebut also solid-state chemistry. In addition, they study not only minerals but all materials related to properties of solids and liquids, for which Bridgman received the Nobel Prize in Physics in 1946. The second major contributor from Harvard was Francis Birch, who was a graduate student in Bridgman’s high-pressure laboratory [as were David Griggs and George Kennedy]. In 1932, two new research ventures were initiated at Harvard: a revitalized program in seismology and a program for comprehensive high-pressure studies devoted to geophysical problems. Birch was invited to lead the new high-pressure research program as Harvard’s first research associate in geophysics.  His most significant contribution appeared in one of the classic papers of geonatural minerals (e.g., structural analogs, but also glasses, melts, and fluids). The father of mineral physics on ‘‘Elasticity and constitution of the Earth’s interior’’ [2]. Here, he is widely aconclusively demonstrated that (1) the mantle is predominately composed of silicate minerals; (2) the upper mantle and lower mantle regions, each essentially homogeneous but of somewhat differing compositions, are separated by a thin transition zone associated with silicate phase transitions; and (3) the inner and outer core are alloys of crystalline and molten iron, respectively, rather than alternative interpretations proposed at the time. The essential details of this model are still valid; only a few refinements have been necessary in the light of subsequent research. 

Accepted to be Francis Birch, whose seminal paper in 1952 summarized the state of knowledge of the elasticity and constitutiording to Robert Hazen [3], “mineral physics is t of the study of mineralogicEal problems through the application of condensed matter physics”. In reality, mineral physicists use not only physics but also solid-state chemistry. In addition, they study not only minerals but all materials related to natural minerals (e.g., structural analogs, but also glasses, melts, and fluids).  Although he never used the term, Francis rth’s interior at that time [2]; however, Birch is widely acknowledged as the ‘‘father of did not use the name “mineral physics.  Orson Anderson often cited the German physicist Eduard Grüneisen as the person who first introduced the term mineral physics [4][5][3,4].

How did the term ‘‘mineral physics’’ become adopted to define an area of research in the geosciences?  Mineral physics is not really a new way of performing research, but it focuses on areas of research that formerly were treated largely as separate from each other. In the mid 20th century, geophysics and mineralogy were two avenues in the overall picture of earth sciences, rarely talking with each other with one based on largescale earth studies such as geomagnetism and seismology, and the other one classifying minerals based on color, hardness, optical properties, and diffraction patterns. Then, geophysicists began to become more interested in the physical properties of minerals and mineralogists began to explore how physical properties depend on atomic structure along with exploiting new tools such as automated X-ray diffractometers, electron microprobes and microscopes, various kinds of spectrometry, digital computers, and synchrotron radiation sources, all of which became generally available to geoscientists in the second half of the 20twentieth century.

Over the last four decades of the 20th century, many laboratories began to conduct experiments on the physical properties of minerals at high pressures and temperatures. Among these were Orson Anderson at Lamont (and later at the University of California Los Angeles-UCLA), John Jamieson at the University of Chicago, Alvin Van Valkenburg at the National Bureau of Standards, William Bassett and Taro Takahashi at the University of Rochester, Ho-kwang Mao and Peter Bell at the Carnegie Institution of Washington, Gene Simmons at the Massachusetts Institute of Technology, Mineo Kumazawa at Nagoya University, Thomas Ahrens at the California Institute of Technology, Gerhard Barsch (and later Earl Graham) at the Pennsylvania State University, Hartmut Spetzler at the University of Colorado, Francis Birch (and later Richard O’Connell) at Harvard University, Murli Manghnani at the University of Hawaii, Syun-iti Akimoto at the University of Tokyo, Jean-Paul Poirier at the Institut de Physique du Globe in Paris and Robert Liebermann at the Australian National University [and later at Stony Brook University with Donald Weidner].

Mineral physics has grown as an international discipline in the Earth sciences and is being pursued in many university academic communities with concomitant funding from a wide array of funding agencies; e.g., NSF, DOE, NASA.  It has become a significant subject of many papers in the journals of the American Geophysical Union; it is also a new section of the AGU [Mineral and Rock Physics].  Thus, the history of mineral physics is of interest, not only to those working in this field, but also to those I seismology, tectonophysics, volcanology, geochemistry and petrology, whose research depends on understanding the role of the fundamental properties of minerals.

The links between mineral physics and other disciplines of geosciences is represented by this graphic designed by Quentin Williams and modified by Ann Lattimore; as such, it has become known as the Williams-Lattimore diagram in the mineral physics world [6][5].

 References

  1. Hazen, R.M. What is mineral physics? EOS Trans. Am. Geophys. Union 1994, 65, 746.
  2. Birch, F. Elasticity and constitution of the Earth’s interior. J. Geophys. Res. 1952, 57, 227–286.
  3. Molnar, P. Personal communication to Robert Liebermann, March 2019.
  4. Liebermann, R. C., The Orson Anderson era of mineral physics at Lamont in the 1960s, Minerals, Special Issue, Mineral physics: In memory of Orson Anderson, published online 4 June 2019, 9(6), 342-360, 2019.
  5. Liebermann, R. C., Reflecting on a Half Century of Mineral and Rock Physics at the AGU, EOS, 101, no. 7, 2020