Miriam Kastner

Miriam Kastner is a Bratislavan born, Israeli raised, American oceanographer and geochemist. Kastner is currently a distinguished professor at Scripps Institution of Oceanography at the University of California, San Diego. She is still recognized by her fundamental contributions to science and is well spoken of amongst colleagues.

Education

Miriam Kastner enjoyed the sciences since she was a child and originally wanted to be a mathematician, however she later decided down the road that, math was not the career for her as there were far fewer careers to pursue in mathematics. Early on Miriam noticed that not many women were scientists, which inspired her to research different sciences.
Kastner attended the Hebrew University of Jerusalem in 1964, where she received a minor in chemistry and a master's degree in geology. After graduation, she wrote her first formal paper about the hydrothermal systems of the Guaymas Basin, in the Gulf of California. Kastner attendedHarvard University, Boston, in 1970, where she was exposed to oceanography and later received her doctorate in geoscience. For three years, Kastner was the only woman in her department while studying at Harvard. Thus, women were not taken very seriously by other faculty members resulting in a discouraging environment. Faculty members also expected less from their female students and counterparts, although there were some who supported Kastner and fellow female academics, such as the Ph.D. committee.

Career

Over the course of her career, Kastner progressed from being an associate professor, to a professor, and is now a distinguished professor at the Scripps Institution of Oceanography, where she participated in writing and publishing 174 articles and journals. Kastner has worked with the Scripps Institution from 1972 till present. Kastner became the second female professor at the Scripps Institute, only two months after the first geophysicist had joined the faculty; this paved the way for many female scientists at the time and in the future. Prior to teaching at Scripps Institution, Kastner worked as a research associate at Harvard University in the department of geological sciences until 1970. In 1971 she worked at the University of Chicago as a research associate in the Department of Geophysical Sciences. Some believe she has accomplished more work than anyone else among the marine geology community and her publications contain high quality data and ideas that show consistency in addressing the big issues in Earth sciences. Miriam Kastner's research is primarily based in mineralogy and petrology, though the most important issue pursued in her career is fluid flow at subducting plate boundaries.
Kastner from the SIO situated in La Jolla, California, demonstrated that we didn't know of the existence of subsea hydrothermal vents until the 1980s. To illustrate the vast scale of these processes, she explained that the entire volume of the ocean circulates through hydrothermal systems about once every five million years, and through global subduction zones approximately once every 200 million years, linking seafloor processes directly to the long-term evolution of the Earth system.
Throughout her long and successful career, Miriam Kastner produced dozens of publications highlighting her key research. Her first publication, dating back to 1965, examined the mineral glauconite and documented its properties. Over the next 15 or so years her research focused more on the analysis of deep sea sedimentation. For the next 20 years of her career she continued her research on deep sea sedimentation but her focus shifted more to hydrogeology and fluid dynamics and the effect of this sedimentation and mineral deposits. In recent years, she has examined isotopes and their concentrations in oceans. Most recently, Miriam has compiled a brief synopsis of her ocean drilling work over the past 50 years.

Academic roles

Along with being a professor, Kastner has served many roles at Scripps Institution of Oceanography, including chair and vice chair of the faculty, associate director and director in the geosciences research division, chair of Academic Senate Committee on Research, as well as curricular group coordinator of geological sciences. From 2003 to 2005, she served on the National Research Council's Ocean Studies Board. As a female in a once male dominated profession, Kastner expressed that it was difficult to garner support from science-related funding agencies. She was glad to see recent improvement on the increase of women pursuing science related degrees, however she believes there is still room for improvement, despite roughly 50% of women being in a science program, but only approximately 20% are field researchers in the institutes. Young women should have more confidence when applying for field research positions, as support for women in the sciences has improved drastically in comparison to her earlier years.

Early career achievements

Much of what Kastner has achieved came from the earlier part of her career when she put her talents to work and directed her focus on the origin of authigenic feldspars, she also focused on zeolites in the oceanic sediments during that time. Delving deeper into the significance of Kastner's work, her first publication named “Notes on the mineralogy and origin of glauconite” documents her findings on the properties and classification of glauconite. Although there were others with documented observations of glauconite the results varied greatly and Kastner was the first to point out that these studies are largely flawed due to the failure to take into account the large deposits of non-structural iron oxides which would ultimately skew the results. With the oceanic sediments she determined that the diagenetic transformations of opal-A to opal-CT and quartz is important to the formation of siliceous marine deposits. Kastner also found that dolomite formation is ultimately controlled by its associated pore-fluid geochemistry. The discovery solved an outstanding problem in carbonate mineral science. Kastner's measurements of the Sr distribution coefficient was critical in building strontium concentrations in calcite, which was ultimately used for paleoclimate studies that are dependent on carbonate Sr proxies, the discovery also was used for indicating carbonate recrystallization. Kastner also worked vigorously on phosphate deposits, her work included a revision of the stability of P-O bonds in apatite and phosphate ions, after the revision there was a recalculation of the ocean residence time of phosphorus. Her research focuses on the geochemistry of fluid work interactions, mostly with ocean chemistry. This encompasses the significance to marine minerals, to gain knowledge and understanding of how the Earth works. Gas hydrate research has interested Kastner and many fellow geo-scientists due to both its possible contribution to global warming, and as a potential energy source provided as a result of the amount of methane found in these oceanic hydrates. By studying these marine events, Kastner has stated that this can allow for people to be better prepared to predict global warming and have the possibility of avoiding sudden climatic response to anthropogenic perturbations.

Key research

Kastner's area of research is “mostly geochemistry on fluid–rock interactions", specifically with seawater. Her research expertise is on the fluctuation of fluids at plate boundaries, specifically where two plates meet to cause earthquakes and at ridge-crests where hypothermal deposits are found. She has authored over 80 scientific articles. Kastner's work is based on numerous studies, including the following:

Long-term monitoring in observatories of marine gas hydrates and implications for climate change, slope stability, and ocean chemistry
On the oceanic contribution of methane to the atmosphere
Chemical paleoceanography: establishing new marine phases based on the ocean's geological history.
Sediment, geochemical and diagenetic processes with emphasis on marine authigenic minerals like phosphates, silicates, carbonates

One of Kastner's most important publications is one of her most recent “50 years of scientific drilling”. This article is particularly significant as it highlights some of her major findings over the last 50 years. This paper does well to review drilling projects as well as highlight major scientific achievements of the work. The major drilling projects mentioned in the article are as follows, the Mohole Project, Joides and the Deep Sea Drilling Project, the Ocean Drilling Program, and the Integrated Ocean Drilling Program and International Ocean Discovery Program. Each of these projects have made significant contributions to the field of geology. The Mohole Project was famous for recovering large deposits of subseafloor basalt, the Joides and the Deep Sea Drilling Project was known for being one of the first to identify and record the sedimentary rock layering of our ocean floors, and the Integrated Ocean Drilling Program and International Ocean Discovery Program made findings that helped shape the education system of undergraduates as well as in grades K-12. Some of the major achievements of scientific ocean drilling are listed below:

Helped set the standard for the geological time scale by refining the geomagnetic time scale and how it relates to astronomical chronologies
Helped link long term climate changes to Earth's orbital variability
Proved that Antarctica was largely iceless approximately 40 million years ago
Discovered the most complete marine records of the Cretaceous/Paleogene mass extinction and potential evidence linking the extinction event to a large asteroid
Provided early evidence of the theory of plate tectonics
Provided the first evidence of the age dependent growth of the oceanic lithosphere
Accurately narrowed down the age of the Earth based on sedimentary record

This is not a complete list.