Materials Science & Engineering, Mechanical Engineering. Novel phases and phase transitions in disordered and strongly correlated electron systems. Engineering piezoelectricity in graphene for mechanical control at nanoscale. 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. Using anaerobic bacteria to convert organic waste to methane gas for fuel to convert wastewater to drinking water. CO2 sequestration in coal beds. Integrating large-scale solar projects with biofuel production in deserts. Methods to project trends in energy technology innovations and associated new business models. Multijunction nanowire solar cells. Combined cooling, heating and power system for the home with thermoacoustic Stirling engine. Electrochemical CO2 and nitrogen gas reduction. Incoming graduate and professional school students may enroll in a week-long energy Climate impacts of converting land use to biofuel crops. EE Student Information, Spring Quarter through Academic Year 2020-2021: FAQs and Updated EE Course List. Multi-scale imaging of energy materials. Combustion, Unconventional Oil & Gas, Geothermal, Photovoltaics. David Packard Building350 Jane Stanford WayStanford, CA  94305, Phone: (650) 723-3931info@ee.stanford.eduCampus Map. Applications include hydrogen and methanol generation through photocatalysis, reduction of methane emissions, PV solar cells, solid oxide fuel cells and batteries. Structure/property of crystalline and polymeric organic semiconductors for photovoltaics. Developing large-scale clean, renewable energy solutions to global warming, air pollution and energy security. CO2 and water electrolysis for energy storage (methane). Energy resources of sedimentary basins. Batteries & Fuel Cells, Electric Grid, Grid Scale Storage, Photovoltaics. Accelerating the conversion of CO2 into carbonate minerals that can be sequestered in silicate rocks rich in magnesium and calcium. Economic Development & Equity, National Security. System-level characterization and aging experiments of energy storage systems. Energy efficiency in optical and wireless access networks. Research pathways to low-carbon energy systems. SIEPR researchers are using the tools of economics to analyze the impact of environmental policy decisions being made in the United States and abroad. Synthetic oxygenated fuels. Stanford School of Earth, Energy & Environmental Sciences. Batteries & Fuel Cells, Photovoltaics, Solar Thermal. Future of stationary power: electricity grid and natural gas infrastructure, system integration and innovative technologies, finance, policy and business models. Doping titanium dioxide nanowires for enhanced photoelectrochemical performance. SLAC - Photon Science, Stanford Institute for Materials & Energy Science, Batteries & Fuel Cells, Superconductors, Photovoltaics. Emissions permit market design, analysis and monitoring.Transmission expansion policy, design and analysis. Subscribe. Impacts on climate of converting land use from food to biofuel crops. Water oxidation with metal-oxide semiconductor anodes. Tailoring solid-state surfaces for effective catalysis in both the production and consumption of energy. Coal-fired fuel cell with CO2 capture. Designer materials and nanoelectronics. Energy in the context of sustainability. Chemical looping combustion with coal and biomass. Coal and biomass conversion in supercritical water for production of liquid fuels. Metabolic processes of anaerobic microorganisms and their application in bioenergy. Applying an electric field to the film to induce directionally dependent properties in polymer crystallites to enhance electron mobility. With core expertise in fluid dynamics, computational engineering, and electrokinetic phenomena, we investigate a concept idea for improving efficiency of plasma-based CO2 converters. ee research @ stanford: the big picturephysical technology & scienceintegrated circuits & power electronicsbiomedical devices, sensors & systemsenergy harvesting & conversionphotonics, nanoscience and quantum technologynanotechnology & nems/memselectronic devicesinformation systems & sciencecontrol & optimizationinformation theory & applicationscommunications systemssocietal Geological carbon storage in sedimentary and magnesium-silicate rocks. “END USE/EFFICIENCY.” Users can filter for specific sub-topics or the entire category. This research could lead to increasing crop yield for biomass. Wireless charging of electric cars. New, fast burning fuels for application to hybrid propulsion. CO2 Capture, Storage & Conversion, Solar Thermal. Geological & Environmental Sciences, SLAC - Photon Science. Energy Modeling Forum, Management Science & Engineering, Climate, Integrated Modeling, Energy Markets, National Security. Developing devices for storing renewable electricity based on chemical transformations. Modeling global oil depletion, or "peak oil," and transitions to oil substitutes. Climate and electricity policy. Names link to individual profile pages, which include contact information. Assessment of air pollutant dispersion and mixing indoors, including the effects of energy-efficient building design strategies on indoor pollutant levels. Aeronautics & Astronautics, Mechanical Engineering. Discovering new, chemically stable nanomaterials for thermionic energy conversion. In the Mechanical Engineering Department at Stanford University, ... (biosynthesis of fuels) and other fields. 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. 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. Wireless technology, including channel modeling, multiuser communications, signal processing and system design, for use in smart grids, automated highways and intelligent home electronics. Management Science & Engineering, Precourt Energy Efficiency Center, Buildings, Energy & Behavior, Heating & Cooling, Transportation, Climate, Integrated Modeling, Energy Markets, Finance & Subsidies, Law, Management & Innovation, Tax & Regulation. 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 In-situ remediation of radioactive waste. A mathematical model for charge transport in semiconducting polymers for insights into the limits of charge mobilities in organic electronic devices. Nanostructured solar cells. Determining the electronic structure of transition metal complexes, which are utilized in oxidation catalysis and fuel cells to facilitate and control oxygen activation and reduction. Obama administration's "Clean Power Plan.". Self-assembly of nanostructures from the natural protein clathrin for experimental battery electrodes. Co-evolution of technology and policy on the business case of low-carbon energy solutions. Understanding mechanisms plants use to produce complex molecules for future use in synthetic production of energy feedstocks. The speed limits and microscopic processes that determine the performance of devices for energy conversion. Waste water: making treatment, as well as water and nutrient recovery, a net producer of energy rather than a consumer. 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. Green Computing, Thermoelectrics, Photovoltaics, Energy & Behavior, Sensors & Data, Transportation. Our Monthly Research News Alert. A new palette for urban water that saves water, energy and money. Energy efficiency technologies, policies and behavior. Decentralized message passing to constantly optimize an electricity network with many different devices, each with its own complex constraints and objective. Modeling natural ventilation in energy efficient buildings using high-fidelity simulations. Interactions between climate and large-scale solar energy projects. Application areas include CO2 sequestration and reservoir simulation. Batteries & Fuel Cells, CO2 Capture, Storage & Conversion, Bioenergy, Photovoltaics. How China and the U.S. could deploy solar energy more efficiently if each one played to its economic strengths. Local response of novel superconductors. Performance of the emerging global market for GHG permits and offsets. Education, Stanford Woods Institute for the Environment, Buildings, Energy & Behavior, Transportation. Optimizing materials for photon-enhanced thermionic emission. Capturing atmospheric CO2 using organic-inorganic hybrid materials. Control of thermal radiation. The long-term behavior of materials, such as those used in radioactive waste disposal. Sootless diesel engine. Micro- and nano-scale mechanical devices, Batteries & Fuel Cells, Nuclear, Photovoltaics. Climate, CO2 Capture, Storage & Conversion, Natural Gas, Unconventional Oil & Gas. Potential energy applications of ultrathin films and amphiphiles. Sugar and ethanol production as a rural development strategy in Brazil. Tiny, highly efficient semiconductor laser for optical data interconnects that use light to communicate with higher speed and smaller energy consumption than conventional electrical interconnects, Electrical Engineering, Materials Science & Engineering. Energy resource planning. Steyer-Taylor Center for Energy Policy & Finance, Economic Development & Equity, Energy Markets, Finance & Subsidies, Management & Innovation, Tax & Regulation. Hybrid and electric vehicles. Tungsten disulfide nanoflakesas a catalyst for producing hydrogen from water. Tools include nanoparticles, metals, alloys, sulfides, nitrides, carbides, phosphides, oxides, and biomimetic organo-metallic complexes. Results of low-carbon energy research at U.S. universities. Co-firing coal and biomass during combustion and gasification. Sustainable, durable construction materials. Buildings, Batteries & Fuel Cells, Climate, Finance & Subsidies, Management & Innovation, Tax & Regulation. Resource management in large, multi-core systems. Multi-exciton generation efficiency in nano-structured materials. Energy technology assessment. CO2 reaction with magnesium-silicate rock in carbon sequestration, with a view to enhancing reaction and reducing cost. Consequences of switching land use to biofuels. Climate benefits of converting biofuel crops from annual plants to perennials. © Stanford University, Stanford, California 94305. Energy production optimization. Emerging computer systems, such as low-power wireless sensor networks and full duplex wireless. Energy interests in transportation systems, energy efficiency and education of scientists and non-scientists in energy policy and technology. Cost competitiveness of renewable energy sources, including solar PV, wind and biofuels. Air Quality, Climate, Land Use, Water, Natural Gas, Economic Development & Equity. Homogeneous charge compression ignition engines. Reducing the environmental impacts of energy systems. Stanford Energy is brought to you by the Precourt Institute for Energy. Analysis of CO2 capture technologies. Energy Resources Engineering. How institutional factors affect the diffusion of technologies, from central electricity generation to cook stoves. Basin and petroleum basin systems modeling. Life-cycle analysis of transportation fuels. Atomic scale synthesis and control of complex oxides heterostructures for energy applications, including superconductors, catalysis and charge storage. Tom's research group is focused on fundamental catalytic processes occurring on solid-state surfaces in both the production and consumption of energy. Transmission electron microscopy to study effects of radiation damage on the size and distribution of quantum dots in solar cells. Using incentive mechanisms and societal networks for reducing congestion-related costs in transportation, both public and private. Geochemistry of mineral surfaces and their reactivity with organic matter. SLAC, Stanford Institute for Materials & Energy Science. Magnetic signatures of materials with quantum mechanical and strongly correlated electron behavior. Energy Research at Stanford The GCEP staff coordinates the Energy Research at Stanford Report, a compilation of abstracts highlighting the wide range of energy-related research taking place across the Stanford campus. 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 Photon-enhanced thermionic emission devices, which use solar heat and light. 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. Making nuclear power safer globally, both in terms of accidents and nuclear weapons proliferation. Thermal transport across interfaces between dissimilar materials. Systems and controls analysis of power systems with distributed generation. Stanford Woods Institute for the Environment. Molecular analysis of organic extracts from sediments and petroleum. Stanford scientists are exploring new technologies that exploit the tremendous amount of heat radiated from the sun. Students may take the Energy Seminar for credit or drop in for talks of interest. Models to predict the performance of enhanced oil recovery methods, particularly gas injection and in-situ combustion. High-temperature superconductivity. Civil & Environmental Engineering, Stanford Woods Institute for the Environment, Water Systems, Economic Development & Equity. Stanford Energy is brought to you by the Precourt Institute for Energy. Environmental economics and industrial organization, with a focus on climate change and energy markets. How the geologic structures created by faults, fractures and folding affect hydrocarbon recovery and the flow of groundwater. Understanding the properties of the transport solutions, commonly a borate guar gum solution. Modern computational approaches to electron and photon dynamics. Chemical Engineering, Mechanical Engineering. Energy Resources Engineering. We’re determined to lead in researching, teaching, and practicing environmental sustainability. Fundamentals of transport of groundwater and contaminants. Funding usually begins in the fall or winter of the year indicated. Electrochemical energy conversion, and storage materials and processes. Optics, photonics and optical materials. 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. Aeronautics & Astronautics, Electrical Engineering. Applications include lithium ion batteries, supercapacitors, CIGS solar cells, transparent electrodes and using carbon nanotubes in microbial fuel cell electrodes. Energy market design and monitoring. The effects of aircraft on climate and pollution. Hydroxylation of methane (and other simple hydrocarbons) using copper and iron to produce methanol, which could reduce oil dependence and GHG emissions. Batteries & Fuel Cells, Grid Scale Storage. Proposal for a revenue-neutral tax on carbon. 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. 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