Stanford University
Showing 141-160 of 418 Results
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Maurice Codespoti Goodman
Research Asst - Graduate,
Research Asst - Graduate, OceansBioI am a PhD candidate in marine ecology and biogeography, studying with Dr. Giulio De Leo at the Hopkins Marine Station. My research employs a variety of statistical and computational tools to examine the effects of climate change on predator-prey interactions in coastal marine ecosystems. By characterizing changes that have already occurred, and building projections under various climate scenarios, my work is aimed at adapting fisheries and marine resource management to a warming world. Before coming to Stanford, I worked alongside Drs. Benjamin Ruttenberg and Jennifer O'Leary, studying the responses of marine communities to disturbance, the population dynamics of marine invertebrates, and the large-scale processes structuring the biogeographic ranges of temperate fishes.
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Diana Gragg
Managing Director Explore Energy, Precourt Institute for Energy
Current Role at StanfordManaging Director, Explore Energy, Precourt Institute for Energy
Core Lecturer, Civil and Environmental Engineering -
Andrea Gray
Director of Finance and Operations, Sustainability Accelerator
BioAndrea joined the Stanford Doerr School of Sustainability in 2023 from Stanford's Center for International Security and Cooperation (CISAC), where she had been the Associate Director for Administration and Finance since 2017. Andrea started her career at Stanford in 2012 as a director at the Graduate School of Business, responsible for delivering innovation and entrepreneurship programs internationally. In 2015, she moved to the School of Medicine as an internal consultant, supporting leadership at the School and two hospitals across a portfolio of initiatives in the areas of international strategy, graduate medical education, clinical expansion, and faculty affairs. Prior to Stanford, Andrea managed a product line at a Fortune 500 company, helped lead a technology startup from conception to acquisition, worked as a strategy consultant, played a leadership role at a grassroots environmental non-profit, and directed an educational foundation. Andrea holds a bachelor's degree from Queen's University in Canada.
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Gemma Guilera Ferre
Managing Director, Sustainability Accelerator
BioDr. Gemma Guilera is a chemist, an entrepreneur and an enabler of innovation. She currently serves as a Managing Director at the Sustainability Accelerator within the Stanford Doerr School of Sustainability.
Prior to joining the Accelerator, Guilera was Senior Manager at Plug and Play tech Center, an innovation platform and early-stage startup investment firm in Silicon Valley. Specializing in sustainable materials and packaging, she facilitated relationships between corporations seeking innovative solutions and the dynamic startup network at Plug and Play. Earlier to this role, Guilera was co-founder and CEO of Moving Beans, a venture backed-up sustainable startup developing more environmentally friendly, home-compostable materials for consumer goods.
During her time in the UK, Guilera was part of the original team that implemented the human-centered, solution-led Accelerator for Cities at Connected Places Catapult, where she led the startup team. The team provided support to startups in their growth journey through strategic multi-stakeholder engagement and accelerator programs. She also developed and led the open call for one of the largest large-scale IoT demonstrators globally, now the EU standard for innovative open calls.
Prior to her work in innovation, Guilera built the X-Ray Absorption Spectroscopy Beamline at ALBA Synchrotron (Spain), overseeing its construction and operation and conducting research in various areas such as catalysis and nanomaterials. Her career began as an industrial post-doc, followed by her role as a scientist at the ESRF (European Synchrotron Radiation Facility), where she worked in the field of heterogeneous catalysis and collaborated with Toyota to co-develop a three-way catalyst for petrol cars.
Gemma holds a BSc in Chemistry from the University of Barcelona, as well as an MSc in Supramolecular Chemistry and a PhD in Organometallic Chemistry from King’s College London. She was selected as one of the finalists in Women in Tech Global Awards 2021. -
Emily Gwynn
Program Coordinator, Energy Science & Engineering
Current Role at StanfordProgram Coordinator, Energy Science & Engineering, Doerr School of Sustainability
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Angela Halfpenny
Director, Integrated Shared Laboratory Management, Stanford Doerr School of Sustainability - Dean's Office
Current Role at StanfordDirector, Integrated Shared Laboratory Management
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Andrew Hennig
Research Asst - Graduate, Oceans
BioAntarctic ice sheet, both of which have exhibited significant mass loss over the past few decades. If the two ice sheets were to fully collapse, they could be responsible for up to 15m of global sea level rise (roughly equal parts from both). This sea level rise would not only pose serious problems for coastal settlements, but cause serious changes to ecosystems, and could profoundly alter the Earth’s ocean circulation.
Current estimates of the mass balance for ice sheets are based primarily on satellite data. This data has become more accurate and more available than ever before, since the 1990s. While estimates can be provided by satellite data, satellites are limited by virtue of the fact that they can only evaluate the surface of the ice shelf. Recent research has shown that a significant amount of the mass loss from the West Antarctic ice sheet is happening underwater, along grounding lines, where deep waters, warmed by global warming, enter the area underneath the ice shelf, and melt the shelves from the bottom. This not only results in mass loss directly, but increases calving of glaciers into the ocean, further accelerating their loss. This melting, below the surface of the ice shelves, cannot be estimated by satellites.
To get a better understanding of the impact of warmer deep waters on glacial retreat in Western Antarctica, we need to measure the melt more directly. Using highly precise measurements of salinity and isotopic composition of seawater in coastal regions of Western Antarctica, we can estimate the amount of glacial meltwater present in the oceanic adjacent to ice sheets. Gaining a greater understanding of the rates and locations of West Antarctic melting will be crucial to developing our understanding of future sea level rise, and other wider impacts.