Materials with unconventional magnetic and electronic properties. New algorithms to improve imaging of reflection seismic data for structural and stratigraphic interpretation. Transportation, CO2 Capture, Storage & Conversion, Combustion. Energy efficient and sustainable building design. Reducing plug loads to achieve net-zero energy buildings. Computing the life-cycle health, environmental and climate change damages associated with different transportation strategies. Electrochemical CO2 and nitrogen gas reduction. Environmental learning and behavior, including transportation. Atomic and molecular manipulation for energy-efficient nanotechnology. Monitoring global GHG emissions. Geological & Environmental Sciences, SLAC - Photon Science. Carbon nanospheres for stable lithium metal anodes. We’re determined to lead in researching, teaching, and practicing environmental sustainability. Course work includes the fundamentals of chemistry, computer science, engineering, geology, geophysics, mathematics, and physics. “GCEP was a creativity engine. Using anaerobic bacteria to convert organic waste to methane gas for fuel to convert wastewater to drinking water. Developing an efficient low-power microprocessor. Advanced characterization of materials. Entrepreneurship education regarding high-growth and technology enterprises, in particular energy-related technologies. Single vortex dynamics in superconductors. Superconductivity, topological insulators and behavior of electrons in low-dimensional materials. Interactions between climate and large-scale solar energy projects. Control of thermal radiation. Developing devices for storing renewable electricity based on chemical transformations. Microbes that convert electricity, CO2 and water into fuels (or precursors) without the use of biomass. Sensor systems for extreme harsh environments, applicable to hydrocarbon exploration, gas turbines, car and plane engines, and geothermal generation. The Energy@Stanford & SLAC course will feature a diverse line-up of Stanford faculty undertaking exciting research in the field of energy. GHG emissions and economic implications of new shale gas supplies. Buildings, Batteries & Fuel Cells, Climate, Finance & Subsidies, Management & Innovation, Tax & Regulation. Designing organizations and governance regimes for sustainable development of energy and civil infrastructure projects. CO2 Capture, Storage & Conversion, Unconventional Oil & Gas. Estimation of fossil-fuel CO2 emissions via atmospheric inversions.Water quality monitoring and contaminant source identification. CO2 and water electrolysis for energy storage (methane). Search form. Energy efficiency analysis. SLAC is a U.S. Department of Energy national laboratory operated by Stanford, conducting research in chemistry, materials and energy sciences, bioscience, fusion energy science, high-energy physics, cosmology and other fields. Nanoscale materials and devices for energy conversion, transport and storage. Net energy analysis of emerging technologies, such as PV and energy storage.Energy systems analysis to guide decisions about providing energy while reducing GHG emissions. Seismic wave propagation in multi-scale heterogeneous reservoirs. Decentralized message passing to constantly optimize an electricity network with many different devices, each with its own complex constraints and objective. Structure/property of crystalline and polymeric organic semiconductors for photovoltaics. Systems and controls analysis of power systems with distributed generation. Ways for the construction industry to overcome barriers to adopting energy-efficient innovations. Power electronics, RF power amplifiers, resonant converters, soft switching topologies and design of power converters for operation in harsh environments. Coal-based power generation involving coal conversion in supercritical water with CO2 capture and aquifer-based sequestration. Research Area: Energy Sustainability. Combustion, Unconventional Oil & Gas, Geothermal, Photovoltaics. Characterization and monitoring of petroleum and carbon storage systems. Possible formation and release of nitrosamine and nitramine carcinogens from amine-based CO2 capture, which is the only currently economical technology for power plant exhaust gases, and techniques to destroy any of these byproducts. Batteries & Fuel Cells, Superconductors, Renewable Fuels, Solar Thermal. Magnetic nanotechnology, spintronics and integrated inductors, with applications in energy conversion and storage. Design of cap-and-trade systems. Metal-oxide semiconductor anodes for oxidation of water. The environmental and economic impacts of U.S. and international environmental policies, including policies to deal with climate change, and with pollution from power plants and automobiles. Earth System Science, Center on Food Security & the Environment. Application areas include CO2 sequestration and reservoir simulation. Homogeneous charge compression ignition engines. Co-evolution of technology and policy on the business case of low-carbon energy solutions. © Stanford University, Stanford, California 94305. CO2 Capture, Storage & Conversion, Energy Markets, Water. Nonequilibrium phonon dynamics. Generating bioenergy in the form of hydrocarbons and electricity from living cells. Aeronautics & Astronautics, Electrical Engineering. Basin and petroleum basin systems modeling. Metabolic processes of anaerobic microorganisms and their application in bioenergy. Energy and climate change policy analysis. Subscribe. New methods for delignification of woody cellulosic biomass. Current trends in energy industries. Understanding energy efficiency behavior selection and plasticity, and tests of adoption. Synthetic oxygenated fuels. Enhanced oil recovery. Our scholars work closely with scientists, engineers, and policymakers to develop and analyze economically viable approaches to CO2 sequestration in coal beds. Some of the activities in this report are sponsored by GCEP, while others are sponsored by outside organizations. Tailoring solid-state surfaces for effective catalysis in both the production and consumption of energy. Control technologies for networked and distributed systems, including the electric system. Risk-adjusted forecasting of electric power load. Theory and modeling for new, energy-related materials and nanomaterials. Arbabian, Boahen, Boneh, Boyd, Candes, Congreve, Dally, Duchi, Dutton, El Gamal, Fan, Glynn, Goldsmith, Harris, Hesselink, Horowitz, Howe, Johari, Kozyrakis, Lall, Lee, Mitra, Montanari, Murmann, Olukotun, Pavone, Poon, Pop, Prabhakar, Rajagopal, Rivas Davila, Saraswat, Solgaard, Tse, Van Roy, Vuckovic, Wong, Ye. Understanding and controlling surface and interfacial chemistry, and materials synthesis. Energy efficiency technology, policy and economics. Geochemistry of mineral surfaces and their reactivity with organic matter. System-level characterization and aging experiments of energy storage systems. Rate constants for reactions of OH with fuels. Stochastic modeling and assessing uncertainty for decision making in geoengineering applications, particularly in modeling oil and gas reservoirs. Understanding the properties of the transport solutions, commonly a borate guar gum solution. New types of long life, safe and inexpensive alkali metal batteries to connect wind and solar sources to the electrical grid. Material processing and fabrication technology for solar concentrators based on graded-index and optical meta-materials to improve output and lower cost in thermal solar and photovoltaic cells. Materials Science & Engineering, Mechanical Engineering. Sensors and actuators for energy conversion. The impact of pricing and information provision on energy demand. Fabrication of nanoscale materials, and study of their electronic, photonic, electrochemical and catalytic properties. New materials such as topological insulators and topological superconductors. Molecular analysis of organic extracts from sediments and petroleum. Using current supercomputers and next-generation high performance systems for multidisciplinary optimization to increase wind turbine power output and reduce noise. Materials Science & Engineering, SLAC - Photon Science. Energy market design and monitoring. Carnegie - Global Ecology, Earth System Science. Matching solar supply with businesses that have price-sensitive demand. Electro-catalysts for renewable fuels and chemicals. Stanford Home Maps & Directions Search Stanford Emergency Info. Stanford Earth and other schools at Stanford are investing heavily in research aimed at developing new approaches, technologies, and policies for a reliable, affordable, and low- or no-carbon energy future. Environmental costs and benefits of hydraulic fracturing, especially on local water, air, human health and climate. Impact of rock type, porosity, pore fluids, temperature, and stress on seismic wave propagation. Use of renewable materials instead of plastics to make structural insulated panels, which improve heating and cooling efficiency in buildings. Managing the global expansion of nuclear power while avoiding the proliferation of nuclear weapons, with special attention to the nuclear aspirations of states such as North Korea and Iran. Earth System Science, Stanford Woods Institute for the Environment. Batteries & Fuel Cells, CO2 Capture, Storage & Conversion, Renewable Fuels. CO2 Capture, Storage & Conversion, Enhanced Oil Recovery, Natural Gas. EE Student Information, Spring Quarter through Academic Year 2020-2021: Integrated Circuits and Power Electronics, Photonics, Nanoscience and Quantum Technology. Optimizing materials for photon-enhanced thermionic emission. Geophysical characterization of the chemical and physical changes that a rock formation undergoes upon the injection of fluids for storage, as with sequestration of CO2, or for the production of fossil energy, i.e., hydraulic fracturing and formation damage.Unpredicted rock alterations can lead to ground contamination, ineffective stimulation and seismic activity. Structural characterization of materials used for energy conversion and storage, especially graphenefor thin films for solar cells, and also lithium-sulfur batteries for electric cars, high-temperature proton exchange membrane for fuel cells. Chemical Engineering, Civil & Environmental Engineering, Water Systems, CO2 Capture, Storage & Conversion, Bioenergy. New, fast burning fuels for application to hybrid propulsion. Electrochemical energy conversion, and storage materials and processes. Developing energy efficient electronic solutions. We combined advances in materials science, biology, physics, chemistry, geology and engineering science with the know-how of our industrial partners,” said Sally Benson , a professor of energy resources engineering and director of GCEP. The TomKat Center supports early-stage research by Stanford faculty in the area of sustainable energy. How the geologic structures created by faults, fractures and folding affect hydrocarbon recovery and the flow of groundwater. Increasing output and reducing costs at large wind farms by positioning smaller, mixing turbines among the primary turbines in conjunction with other new management approaches. How China and the U.S. could deploy solar energy more efficiently if each one played to its economic strengths. The back-end of the nuclear fuel cycle, mainly nuclear materials and the geochemistry of radionuclides with application to permanent geologic disposal. How institutional factors affect the diffusion of technologies, from central electricity generation to cook stoves. Hydrogen from biomass by developing a synthetic enzyme pathway to produce hydrogen from NADPH. Trip estimation techniques to better manage hybrid vehicle batteries. U.S. Environmental Protection Agency enforcement. In the Mechanical Engineering Department at Stanford University, ... (biosynthesis of fuels) and other fields. Stanford School of Earth, Energy & Environmental Sciences. Sustainable Stanford is a university-wide effort to reduce our environmental impact, preserve resources, and show sustainability in action. With an unparalleled ecosystem of energy research groups as well as extensive facilities and infrastructures at Stanford and SLAC, we enjoy a distinct advantage in exploring the interesting physics in the field of energy research and nanoscience. A new palette for urban water that saves water, energy and money. Emerging business models at the interface of data sharing platforms and energy systems. Nanostructured solar cells. Search In-situ remediation of radioactive waste. Emissions permit market design, analysis and monitoring.Transmission expansion policy, design and analysis. Transmission electron microscopy to study effects of radiation damage on the size and distribution of quantum dots in solar cells. This research could lead to increasing crop yield for biomass. Efficient data centers. Combined cooling, heating and power system for the home with thermoacoustic Stirling engine core fueled by natural gas and solar thermal energy. Energy's impacts on climate change. Modeling energy's effects on health and climate. Energy Research Area: CO2 Capture, Storage & Conversion, Enhanced Oil Recovery, Natural Gas, Unconventional Oil & Gas. Turbulence interactions with dispersed particles and droplets, such as with pulverized coal combustors and fast-fluidized beds. Materials Science & Engineering, Precourt Energy Efficiency Center, Buildings, Transportation, Climate, Integrated Modeling, Land Use, Economic Development & Equity, Energy Markets, Finance & Subsidies, Management & Innovation, Tax & Regulation. Urban water infrastructure and the water/energy nexus. Innovation strategy and management within the global energy transition. Turning wastewater treatment into a producer of energy instead of a consumer. Incoming graduate and professional school students may enroll in a week-long energy Global potential of bioenergy. Low-to-intermediate temperature solid oxide fuel cells. Applying an electric field to the film to induce directionally dependent properties in polymer crystallites to enhance electron mobility. Lithium-ion battery modeling, estimation, control and optimization. Diamondoids-nanostructured diamond. Energy technology assessment. This database covers energy-related research at Stanford, SLAC, Hoover Institution and the Carnegie Institution departments at Stanford. Photon-enhanced thermionic emission devices, which use solar heat and light to generate electricity. Developing large-scale clean, renewable energy solutions to global warming, air pollution and energy security. Tungsten disulfide nanoflakesas a catalyst for producing hydrogen from water. Center on Food Security & the Environment, Economics, Climate, Land Use, Economic Development & Equity, Bioenergy. Applications include hydrogen and methanol generation through photocatalysis, reduction of methane emissions, PV solar cells, solid oxide fuel cells and batteries. Numerical modeling of flow and transport in porous rock with emphasis on unstable multiscale dynamics. Hybrid and electric vehicles. Atomic-scale structure and dynamics of the ion conducting oxide ceramic materials at the heart of solid oxide fuel cells, with the aim of optimizing performance and lowering cost. Tracer analysis of fractures. Buildings, Electric Grid, Sensors & Data, Transportation. Energy Research at Stanford As a global citizen and leader in science and technology, Stanford is tackling one of the most pressing issues of our time — energy . Oxidative conversion of natural gas into liquid fuels without CO2 release. Developing a community-based program for reducing residential energy use, working with Girl Scouts. Biosynthesis and molecular-scale recycling of bioplastics and biocomposites. Continuous passive seismic monitoring for detection of CO2 plumes in geologic sequestration projects. Economics of CO2 capture by fossil fuel power plants. Stanford Energy is brought to you by the Precourt Institute for Energy. Developing new computational methods to design and analyze renewable energy, including solar thermal devices. Climate change, energy conservation and power supplies pose some of today’s greatest challenges. Bits & Watts Initiative Bits & Watts develops innovations for the electric grid needed to enable reliance on intermittent power and distributed energy resources, while keeping the grid secure and affordable. Characteristics of of airborne particles emitted from urban combustion sources. Optimization of oil field development and operations. Our Monthly Research News Alert. In 2009, Chu became President Barack Obama’s secretary of energy, and then returned to Stanford’s faculty both in physics and at the medical school in 2013. Operational management challenges for some cleantech firms. Water oxidation with metal-oxide semiconductor anodes. Assessing how to transition to sustainable and low carbon energy systems, based on the technologies that can address future energy needs and the decision-making process followed by various agents in the economy. Climate benefits of converting biofuel crops from annual plants to perennials. Disinfection byproducts in drinking water impacted by shale gas wastewater. A mathematical model for charge transport in semiconducting polymers for insights into the limits of charge mobilities in organic electronic devices. Reducing wind power costs by improving forecasts and buying replacement power later. Developing monocrystalline germanium III-V solar cell with efficiencies near the best multi-junction cells and manufacturing cost approaching the conventional crystalline silicon technology. Chemical and physical processes of geothermal systems. How different scenarios of expanded biofuels production in rich and poor countries will affect global and regional food prices, farmer incomes, food consumption by the poor, and climate. Coal-fired fuel cell with CO2 capture. Our current, highly diverse approach to research positions us well to contribute to this rapidly changing landscape. The construction industry's barriers to adopting energy-efficient innovations. Photon-enhanced thermionic emission devices, which use solar heat and light. Unmanned electric vehicles. CO2 Capture, Storage & Conversion, Enhanced Oil Recovery. High-temperature superconductivity. 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