Abstract: Humans and natural ecosystems are exposed to toxic metals from many sources and following many exposure pathways. In this seminar, Dr. Blum will explain how small variations in the isotopic compositions of lead and mercury are created and how they can be used to unravel many of the mysteries of the exposure of these metals to people and ecosystems.

Speaker bio: Joel Blum holds the MacArthur and Keeler Professorships in Earth and Environmental Sciences at the University of Michigan. He earned his B.A. from CWRU, M.S. from the University of Alaska, and Ph.D. from Caltech. Professor Blum’s research focuses on the sources, fate, and cycling of metals and on the application of stable and radiogenic isotopes across earth sciences, chemistry and ecology. He has studied topics that include granite petrogenesis, ore deposits, meteorites, impacts, soils, forest nutrient cycling, hydrogeochemistry, terrestrial and aquatic foodwebs, animal migration, atmospheric chemistry and chemical oceanography. Blum is a past editor of Chemical Geology and Elementa and is currently the editor of the American Chemical Society’s journal Earth and Space Chemistry. He is a Fellow of the Geochemical Society, the American Geophysical Union, the Geological Society of America, and the AAAS. He was awarded the Patterson Medal of the Geochemical Society for his work on the application of mercury isotopes in the environment. 

Abstract: In 2015 nations agreed to the Sustainable Development Goals, including ending poverty, protecting the planet, and ensuring prosperity for all. To accomplish them, we need to find synergies across the seventeen goals. Fortunately, some co-benefits are clear.  Cutting greenhouse gas emissions does much more than fight climate change.  It saves water and improves water quality. It saves lives, too, as witnessed by the ~20,000 or more people who die from coal pollution each year in the United States, with a million more people worldwide. The low-carbon economy will help stabilize national security, create net jobs, and more.

About the Speaker: Rob Jackson is Douglas Provostial Professor and Chair of the Earth System Science Department at Stanford University and a Senior Fellow in Stanford's Woods Institute for the Environment and Precourt Institute for Energy (jacksonlab.stanford.edu).  As an environmental scientist, he chairs the Global Carbon Project (globalcarbonproject.org), an international organization that tracks natural and anthropogenic greenhouse gas emissions.  His photographs have appeared in many media outlets, including the NY Times, Washington Post, and USA Today, and he has published several books of poetry. Jackson is a Fellow of the American Geophysical Union and the Ecological Society of America and was honored at the White House with a Presidential Early Career Award in Science and Engineering.

Abstract: Globally, infectious diseases are emerging at an increasing rate. Vector-borne diseases in particular present one of the biggest threats to public health globally. Many of these diseases are zoonotic, meaning they cycle in animal populations but can spillover to infect humans. As a result, risk to humans of acquiring a zoonotic or vector-borne disease largely depends on the distribution and abundance of the reservoir hosts—the species of animals that pathogens naturally infect—as well as of the vector species. The ecology of many reservoir hosts and vectors is rapidly changing due to global change, which will fundamentally alter human disease risk in as yet unforeseen ways. In this talk, I will present and discuss three lines of research aimed at identifying drivers of disease emergence and risk at multiple spatial scales including 1) the ecological and environmental drivers of Lyme disease in California, 2) the roles of human behavior and land use in driving human Lyme disease in the northeastern US, and 3) effects of deforestation, land use policy and socio-ecological feedbacks in driving malaria in the Brazilian Amazon.

About the Speaker: Andrew MacDonald is a disease ecologist and a National Science Foundation Postdoctoral Fellow in Biology at Stanford University. He received his PhD from the Department of Ecology, Evolution and Marine Biology at the University of California, Santa Barbara in September 2016. His dissertation focused on the effect of land use and environmental change on tick-borne disease risk in California and the northeastern US. His current work focuses on coupled natural-human system feedbacks and land use change as drivers of mosquito-borne disease, with a focus on malaria in the Amazon basin.

Abstract: Over the past decade, the proven ability to produce large quantities of natural gas from organic-rich shale formations in North America has shown the potential to change the energy picture in many parts of the world. Over the past five years there have been discoveries of large natural gas fields in the eastern Mediterranean and off the east coast of Africa.  These enormous resources have the potential to dramatically change the global energy system – for better, or for worse. In this talk I will discuss steps that can be taken to assure that natural gas resources are developed in an optimally efficient and environmentally responsible manner. Responsible development of shale gas resources using horizontal drilling and multi-stage hydraulic fracturing has the potential to substantially reduce greenhouse gas emissions and, in the near term, significantly reduce air pollution in many cities in the developing world. I will discuss several on-going research projects investigating the wide variety of factors affecting successful gas production from these extremely low permeability formations and procedures for managing the risks of earthquakes triggered by injection of hydraulic fracturing waste water.

About the Speaker: Dr. Mark D. Zoback is the Benjamin M. Page Professor of Geophysics at Stanford University and Director of the Stanford Natural Gas Initiative.  Dr. Zoback conducts research on in situ stress, fault mechanics, and reservoir geomechanics with an emphasis on shale gas, tight gas and tight oil production.  He currently directs the Stanford Natural Gas Initiative and is co-director of the Stanford Center on Induced and Triggered Seismicity. He is the author of a textbook entitled Reservoir Geomechanics published in 2007 by Cambridge University Press and the author/co-author of over 300 technical papers. Dr. Zoback was the founder of GeoMechanics International, a software and consulting company that was acquired by Baker Hughes in 2008. Dr. Zoback has received a number of awards and honors, including the 2006 Emil Wiechert Medal of the German Geophysical Society and the 2008 Walter H. Bucher Medal of the American Geophysical Union.  In 2011, he was elected to the U.S. National Academy of Engineering and in 2012 elected to Honorary Membership in the Society of Exploration Geophysicists.  He is the 2013 recipient of the Louis Néel Medal of the European Geosciences Union and named an Einstein Chair Professor of the Chinese Academy of Sciences. In 2015 he received the Robert R. Berg Outstanding Research Award of the AAPG 2016 received the American Geosciences Institute Award for Outstanding Contribution to Public Understanding of Geosciences. He served on the National Academy of Engineering committee investigating the Deepwater Horizon accident and the Secretary of Energy’s committee on shale gas development and environmental protection. He also advised a Canadian Council of Academies panel investigating the same topic and served on the National Academy of Sciences Advisory Board on drilling in the Gulf of Mexico.

Abstract: Concerns are mounting that changes in climate, land use, species invasions, and connectivity are changing the global landscape of infectious diseases. Ecological complexity makes these anthropogenic effects on infectious disease difficult to predict. Using data-driven mathematical models, I will show how mosquito-transmitted diseases such as malaria, dengue, and chikungunya may shift with changing climate. I will then discuss sources of uncertainty and how ecological understanding can help to mitigate future shifts in disease risk. Finally, I will introduce the new Center for Disease Ecology, Health, and Development based at Stanford University, which will work to improve human health and well-being through ecological solutions to infectious disease.

About the Speaker: Erin Mordecai has been an Assistant Professor in Biology at Stanford University since January 2015. Her research focuses on the ecology and evolution of infectious diseases in humans and natural systems, and in particular how infectious diseases respond to global change. She graduated from the University of Georgia in 2007 and received her PhD at the University of California Santa Barbara in 2012. She then completed an NSF Postdoctoral Research Fellowship in Biology at the University of North Carolina at Chapel Hill and North Carolina State University. 

Abstract: The Cold War rivalry between the United States and the Soviet Union lasted for much of the second half of the 20th Century. While the superpowers never engaged directly in full-scale armed combat, a nuclear arms race became the centerpiece of a doctrine of mutually assured destruction, and prompted a mass production of plutonium, and the designing, building, and testing of large numbers of nuclear weapons. In more than 50 years of operation, the Cold War battlefields created over 100 metric tons of plutonium, produced tens of thousands of nuclear warheads, oversaw more than 1000 detonations, and left behind a legacy of contaminated facilities, soils, and ground water.  

The extent of long-term adverse health effects will depend on the mobility of plutonium and other actinides in the environment and on our ability to develop cost-effective scientific methods of removing or isolating actinides from the environment. Studying the complex chemistry of plutonium and the actinides in the environment is one of the most important technological challenges, and one of the greatest scientific challenges in actinide science today.

I will summarize our current understanding of actinide chemistry in the environment, and how that understanding was used in the decontamination and decommissioning of the Rocky Flats Site, where plutonium triggers for U.S. nuclear weapons were manufactured. At Rocky Flats, synchrotron radiation measurements made at the Stanford Synchrotron Radiation Laboratory were developed into a science-­based decision-­making tool that saved billions of dollars by focusing Site-­directed efforts in the correct  areas, and aided the most extensive cleanup in the history of Superfund legislation to finish one year ahead of schedule, ultimately resulting in billions of dollars in taxpayer savings.

About the Speaker: David L. Clark received a B.S. in chemistry in 1982 from the University of Washington, and a Ph.D. in inorganic chemistry in 1986 from Indiana University. His thesis work received the American Chemical Society’s Nobel Laureate Signature Award for the best chemistry Ph.D. thesis in the United States. Clark was a postdoctoral fellow at the University of Oxford before joining Los Alamos National Laboratory as a J. Robert Oppenheimer Fellow in 1988. He became a Technical Staff Member in the Isotope and Nuclear Chemistry Division in 1989. Since then he has held various leadership positions at the Laboratory, including program management for nuclear weapons and Office of Science programs, and Director of the Glenn T. Seaborg Institute for Transactinium Science between 1997-2009. He has served the DOE as a technical advisor for environmental stewardship including the Rocky Flats cleanup and closure (1995-2005), closure of High Level Waste tanks at the Savannah River Site (2011), and as a technical advisor to the DOE High Level Waste Corporate Board (2009-2011). He is currently the Program Director for the National Security Education Center at Los Alamos, a Fellow of the American Association for the Advancement of Science, a Laboratory Fellow, and Leader of the Plutonium Science and Research Strategy for Los Alamos. His research interests are in the molecular and electronic structure of actinide materials, applications of synchrotron radiation to actinide science, behavior of actinide and fission products in the environment, and in the aging effects of nuclear weapons materials. He is an international authority on the chemistry and physics of plutonium, and has published over 150 peer-reviewed publications, encyclopedia and book chapters.