Electrical Engineering, SLAC - Photon Science. The kinetics and thermodynamics of protein self assembly for potential applications including photovoltaics and energy storage. How geochemical reactions of CO2 injection change the seismic attributes of rocks. Emerging computer systems, such as low-power wireless sensor networks and full duplex wireless. Energy Resources Engineering. Reducing corporate carbon footprint through operations and supply chain management. (Instructor) Expertise in life-cycle environmental impacts and tradeoffs in the energy industry. Energy Markets and Policy GSBGEN 336 (Win) Energy, the Environment, and the Economy ECON 17N (Win) Regulatory Economics ECON 158 (Win) Regulatory Economics LAW 1056 (Win) Research Methods and Policy Applications I INTLPOL 301A (Aut) Research Methods and Policy Applications II INTLPOL 301B (Win) Sustainable Energy for 9 Billion ENERGY 104 (Spr) Buildings, Energy & Behavior, Sensors & Data. The back-end of the nuclear fuel cycle, mainly nuclear materials and the geochemistry of radionuclides with application to permanent geologic disposal. Batteries & Fuel Cells, Unconventional Oil & Gas. Impact of deliberative polling, (which explores how people's opinions would change if they were more informed), on energy choices, attitudes toward renewable energy and energy conservation. Oxide-derived metal nanoparticle catalysts. Rate constants for reactions of OH with fuels. Molecular analysis of organic extracts from sediments and petroleum. Steyer-Taylor Center for Energy Policy & Finance, Economic Development & Equity, Energy Markets, Finance & Subsidies, Management & Innovation, Tax & Regulation. Stanford Energy is brought to you by the Precourt Institute for Energy. Climate and electricity policy. Application areas include CO2 sequestration and reservoir simulation. Photovoltaic absorbers from earth-abundant elements. Trip estimation techniques to better manage hybrid vehicle batteries. Search form. Enhanced geothermal systems. Energy-Efficient computing. Control technologies for networked and distributed systems, including the electric system. Gas mileage standards. Developing devices for storing renewable electricity based on chemical transformations. Synthesis of functional organic and polymer materials for numerous energy applications, such asnanostructured polymers for low-cost, stretchable batteries and PV cells, and thin-film organic PV cells. Batteries & Fuel Cells, Buildings, Thermoelectrics, Transportation. Electronic liquid crystalline phases of matter. Stanford Woods Institute for the Environment. Resources for Current Students. Sootless diesel engine. Energy market design and monitoring. Reservoir geomechanics with emphasis on shale gas and tight gas reservoirs, hydraulic fracturing, the occurrence of induced and triggered earthquakes, and the feasibility of long-termgeologic sequestration of CO2. Creating valuable products from organic waste streams. With core expertise in fluid dynamics, computational engineering, and electrokinetic phenomena, we investigate a concept idea for improving efficiency of plasma-based CO2 converters. Modeling and control of exhaust gas and particulate mitigation devices. Finding natural gas leaks in urban distribution systems. Materials for the reversible sequestration of pollutants and for electro- and photo-catalytic conversions relevant for clean energy. Communal anaerobic digesters as a waste-to-energy strategy to provide sanitation and clean energy, while reducing greenhouse gas emissions relative to conventional septic tanks. Metabolic processes of anaerobic microorganisms and their application in bioenergy. Materials Science & Engineering, Mechanical Engineering. Green energy-efficient networks. Designing "stealth interventions" that harness the motivating characteristics of social movements to promote the overlapping goals of environmental sustainability and health. Earth System Science, Stanford Woods Institute for the Environment. Impacts on climate of converting land use from food to biofuel crops. Chemical looping combustion with coal and biomass. Modern computational approaches to electron and photon dynamics. Chemical Engineering, Mechanical Engineering. Uncertainty and learning in strategic contexts regarding the provision of public goods, mostly in the context of international environmental agreements. Ultrafast properties of nanoscale materials. Models to predict the performance of enhanced oil recovery methods, particularly gas injection and in-situ combustion. Methods to project trends in energy technology innovations and associated new business models. Discovering new, chemically stable nanomaterials for thermionic energy conversion. Power electronics, RF power amplifiers, resonant converters, soft switching topologies and design of power converters for operation in harsh environments. Correlated electron materials, in which the low energy degrees of freedom behave qualitatively differently than a free electron gas. Fabrication of nanoscale materials, and study of their electronic, photonic, electrochemical and catalytic properties. Characterizing and modeling the fundamental micromechanical and photochemical mechanisms that dictate the reliability and lifetimes of emerging energy technologies, including solar cells and their modules, PEM fuel cells, and batteries. Our current, highly diverse approach to research positions us well to contribute to this rapidly changing landscape. Circuit, architecture and application optimization tools to minimize energy needed for each task. Geothermal, oil and gas reservoir engineering. The mission of the Energy Resources Engineering major is to provide students with the engineering skills and foundational knowledge needed to flourish as technical leaders within the energy industry. Micro- and nano-scale mechanical devices, Batteries & Fuel Cells, Nuclear, Photovoltaics. Using molecular beam epitaxy of III-V compound semiconductor materials to investigate new materials and nano structuring for high efficiency solar cells and photo electrochemical water splitting for the generation of hydrogen. Electricity and petroleum markets analysis. Sign up for our email. Electro-catalysts for renewable fuels and chemicals. Geologic characterization of petroleum reservoirs, especially deep-water reservoirs. Batteries & Fuel Cells, Buildings, Photovoltaics. Applying this to new materials and processes for next generation low-cost solar cells, fuel cells and catalysts. Developing an efficient low-power microprocessor. Energy Resources Engineering. Future of stationary power: electricity grid and natural gas infrastructure, system integration and innovative technologies, finance, policy and business models. Interactions between climate and large-scale solar energy projects. Assessment of air pollutant dispersion and mixing indoors, including the effects of energy-efficient building design strategies on indoor pollutant levels. Optics, photonics and optical materials. We teach courses and perform research relevant to the production and transformation of energy resources. Environmental costs and benefits of hydraulic fracturing, especially on local water, air, human health and climate. Topological phases of matter. Sensor systems for extreme harsh environments, applicable to hydrocarbon exploration, gas turbines, car and plane engines, and geothermal generation. CO2 Capture, Storage & Conversion, Energy Markets, Water. CO2 Capture, Storage & Conversion, Unconventional Oil & Gas. Sequestration of greenhouse gases in oil and gas reservoirs.Physics of oil recovery at scales from pore to reservoir. 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. Sustainable Stanford is a university-wide effort to reduce our environmental impact, preserve resources, and show sustainability in action. Novel phases and phase transitions in disordered and strongly correlated electron systems. Bioinspired redox catalysts by discrete metal complexes on surfaces, for CO2 capture and reduction of O2 to water in ambient-temperature fuel cells.Strategies to make interfaces in dye-sensitized solar cells less chemically reactive. New ways to synthesize graphene and carbon nanotube architectures for potential future device applications, such as fuel cells, catalysis, and lithium-air and nickel-metal batteries. GHG emissions and economic implications of new shale gas supplies. Models for applying hydraulic fracturing to geothermal systems. Underestimation of U.S. methane emissions from oil and natural gas extraction and processing, (as well non-energy sources). 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. Water oxidation with metal-oxide semiconductor anodes. New, fast burning fuels for application to hybrid propulsion. Discovering new, chemically stable nanomaterials for thermionic energy conversion. Producing ethanol from carbon monoxide gas with a copper catalyst. Novel photonics for green networks. Coal and biomass conversion in supercritical water for production of liquid fuels. Understanding mechanisms for high-temperature superconductors. “END USE/EFFICIENCY.” Users can filter for specific sub-topics or the entire category. Nonequilibrium phonon dynamics. U.S. Environmental Protection Agency enforcement. Analysis of CO2 capture technologies. Enhanced oil recovery. Angle-resolved photoemission spectroscopy studies of strongly correlated electron systems, in particular the high temperature superconductors. The construction industry's barriers to adopting energy-efficient innovations. Developing monocrystalline germanium III-V solar cell with efficiencies near the best multi-junction cells and manufacturing cost approaching the conventional crystalline silicon technology. Flow and heat transfer in complex turbulent flows. Interactions between climate change, biofuel mandates, and energy and agriculture markets. Carbon-based devices. Modeling energy's effects on health and climate. We’re determined to lead in researching, teaching, and practicing environmental sustainability. Environmental economics and industrial organization, with a focus on climate change and energy markets. Systems and controls analysis of power systems with distributed generation. Diamondoids-nanostructured diamond. Synthesizing and characterizing polymer electrolyte membranes for fuel cells, both acidic and alkaline. Your source for engineering research and ideas Coal-fired power with CO2 capture via combustion in supercritical saline aquifer water. Electrochemical energy conversion, and storage materials and processes. SLAC - Photon Science, Stanford Institute for Materials & Energy Science, Batteries & Fuel Cells, Superconductors, Photovoltaics. Global Climate and Energy Project (GCEP), long-term research effort led by Stanford University for the development of a global energy system with low greenhouse emissions Development of laser-based diagnostics to optimize performance and minimize pollution of combustion and propulsion systems. New types of long life, safe and inexpensive alkali metal batteries to connect wind and solar sources to the electrical grid. Modeling global oil depletion, or "peak oil," and transitions to oil substitutes. Multi-exciton generation efficiency in nano-structured materials. Optimization of oil field development and operations. How the geologic structures created by faults, fractures and folding affect hydrocarbon recovery and the flow of groundwater. Continuous passive seismic monitoring for detection of CO2 plumes in geologic sequestration projects. EE Student Information, Spring Quarter through Academic Year 2020-2021: FAQs and Updated EE Course List. Climate impacts of converting land use to biofuel crops. Stanford Energy Research: Year in Review 2018-19. Converting CO2 and water into sustainable fuels and chemicals. 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. Energy efficiency technology, policy and economics. Enhanced Oil Recovery, Unconventional Oil & Gas, Geothermal. Understanding energy efficiency behavior selection and plasticity, and tests of adoption. Since 2010, we have committed over $6 million to 21 such research projects, which we call "seed grants." Impact on power grid reliability from widespread use of distributed energy resources. Understanding mechanisms plants use to produce complex molecules for future use in synthetic production of energy feedstocks. Stanford Home Maps & Directions Search Stanford Emergency Info. Mechanical Engineering, Precourt Institute, Thermoelectrics, Batteries & Fuel Cells, Electric Grid, Grid Scale Storage, Climate, CO2 Capture, Storage & Conversion, Finance & Subsidies, Management & Innovation, Renewable Fuels. Deep-water sedimentation, especially using outcrops and cores to study the processes by which coarse sediment is transported and deposited in the deep sea. Models for new energy paradigms for developing novel materials for superconductors, photovoltaics and batteries. Developing large-scale clean, renewable energy solutions to global warming, air pollution and energy security. Venture capital formation for energy technologies. CO2 reaction with magnesium-silicate rock in carbon sequestration, with a view to enhancing reaction and reducing cost. The curriculum is designed to prepare students for immediate participation in many aspects of the energy in… Using avatars and virtual reality simulations to reduce energy use through reexamination of personal energy behavior and by connecting specific energy use and environmental consequences. Structure/property of crystalline and polymeric organic semiconductors for photovoltaics. We combine theory, experiments, and computation to understand and influence the global energy resources landscape. Synthesis of models from experimental and field data. Electrocatalysts to convert CO2 and feedstocks to higher value materials. Emerging business models at the interface of data sharing platforms and energy systems. Economics, Program on Energy & Sustainable Development, Energy & Behavior, Electric Grid, Water, Energy Markets, Finance & Subsidies, Management & Innovation, Tax & Regulation. Sugar and ethanol production as a rural development strategy in Brazil. Topological phenomena in these topological materials and their interplay with conventional materials such as superconductors and ferromagnets. Transportation, Batteries & Fuel Cells, Electric Grid, Grid Scale Storage. 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. HVAC energy efficiency. Names link to individual profile pages, which include contact information. Engineering piezoelectricity in graphene for mechanical control at nanoscale. Topics for filtering under “Energy Research Area” are in six categories in capital letters, e.g. Controlling atomic scale structure of thin films and nanomaterials for use in photovoltaics and hydrogen storage. Superconductivity, topological insulators and behavior of electrons in low-dimensional materials. Coal-based power generation involving coal conversion in supercritical water with CO2 capture and aquifer-based sequestration. Methane leaks from US natural gas system. David Packard Building350 Jane Stanford WayStanford, CA  94305, Phone: (650) 723-3931info@ee.stanford.eduCampus Map. Green networks for office and residential buildings. 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. Electron transfer dynamics. Development of silicon-based microphotonic functionality and plasmonic devices to manipulate the flow of light at the nanoscale. Energy efficient and sustainable building design. Energy and climate change policy analysis. Two-phase flow in fuel cell microchannels. Advanced characterization of materials. Reducing wind power costs by improving forecasts and buying replacement power later. Emissions permit market design, analysis and monitoring.Transmission expansion policy, design and analysis. Failure to account for geography of trade leads to an overstatement of GHG emissions from U.S. biofuel policies of nearly 100 percent. Aspects of petroleum genesis, production and environmental remediation of oil spills. Multijunction nanowire solar cells. Fundamental and applied electrochemistry: solar fuels, fuel cells, and batteries. Explore energy research at Stanford by clicking on the research area and key topics below. Wireless charging of electric cars. 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. Economic, political and food-security implications of American ethanol. Unconventional superconductivity. Incoming graduate and professional school students may enroll in a week-long energy Multijunction photovoltaic cell using nanowire-based subcells connected in parallel and a plasmonic electrode serving both as a lateral spectral filter and as a light concentrator. Hydrogen transport and hydride formation in metals, alloys and intermetallic compounds for use in vehicular fuel cells and batteries.Materials and phenomena in lithium-ion batteries. New algorithms to improve imaging of reflection seismic data for structural and stratigraphic interpretation. Cost competitiveness of alternative drivetrains for mobility. Seismic wave propagation in multi-scale heterogeneous reservoirs. Capturing atmospheric CO2 using organic-inorganic hybrid materials. Overview of advanced batteries. CO2 sequestration in coal beds. Hydrogen absorption and desorption in individual palladium nanocrystals. Produce scientific knowledge to guide policies on energy extraction and global warming. Mechanisms for directed and efficient channeling of solar energy to chemical energy. Key ares of research include radiative cooling, photon-enhanced thermionic emission (PETE) and thermophotovoltaic technologies that use combine solar heat and photovoltaic energy to produce electricity. Photon-enhanced thermionic emission devices, which use solar heat and light to generate electricity. Basin and petroleum basin systems modeling. Tools include nanoparticles, metals, alloys, sulfides, nitrides, carbides, phosphides, oxides, and biomimetic organo-metallic complexes. Study of heat transfer and energy conversion processes, such as thermoelectric and photonic, at nanoscale. Surveys documenting public beliefs about global warming and preferences for energy policy for more than 15 years. Applications include lithium ion batteries, supercapacitors, CIGS solar cells, transparent electrodes and using carbon nanotubes in microbial fuel cell electrodes. Thermophotovoltaics. Integration of energy and environmental performance indicators, value and payback time in design of energy-efficient buildings. Fundamental laser-matter interactions in solids in the high-field limit. Single vortex dynamics in superconductors. Co-firing coal and biomass during combustion and gasification. 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. Behavior of electrons confined to nanostructures. Turbulence interactions with dispersed particles and droplets, such as with pulverized coal combustors and fast-fluidized beds. Using anaerobic bacteria to convert organic waste to methane gas for fuel to convert wastewater to drinking water. Using control systems to reduce the environmental impact of automobiles. Quantifying wind, water, and solar energy resources and reducing the impacts of their intermittency. System-level characterization and aging experiments of energy storage systems. Developing an oxygen-tolerant iron-based hydrogenase for a photosynthetic microorganism to produce hydrogen from sunlight. U.S. energy policy and its effects on domestic and international political priorities, national security, the economy and global climate. Sequestering CO2 in deep underground formations. 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. The Energy@Stanford & SLAC course will feature a diverse line-up of Stanford faculty undertaking exciting research in the field of energy. EE Student Information, Spring Quarter through Academic Year 2020-2021: Integrated Circuits and Power Electronics, Photonics, Nanoscience and Quantum Technology. © Stanford University, Stanford, California 94305. Inference of fracture geometry from resonant frequencies and attenuation.Fault damage zones impact on the flow characteristics of fractured reservoirs, and predicting fault damage zones. © Stanford University, Stanford, California 94305. Entrepreneurship education regarding high-growth and technology enterprises, in particular energy-related technologies. Such skills and knowledge include resource assessment, choices among energy alternatives, and carbon management, as well as the basic scientific background and technical skills common to engineers. Hoover Task Force on Energy Policy, Precourt Energy Efficiency Center, Precourt Institute, Nuclear, Finance & Subsidies, Law, Management & Innovation, National Security, Tax & Regulation. Improving methods for use of atmospheric observations of GHG from remote sensors. Making nuclear power safer globally, both in terms of accidents and nuclear weapons proliferation. 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. Of technology and policy on the business case of low-carbon energy solutions are significant strands in the mechanical Engineering at... Spintronics and Integrated inductors, with a copper catalyst from water Forum, Management & Innovation Tax! Following centers, programs and initiatives are significant strands in the area of sustainable,. Are formed and destroyed in combustion in Bioenergy their reactivity with organic matter Engineering. Engineering piezoelectricity in graphene for mechanical control at nanoscale shale gas supplies, mostly in the arena of climate and... 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