Modeling energy's effects on health and climate. Angle-resolved photoemission spectroscopy studies of strongly correlated electron systems, in particular the high temperature superconductors. Chemistry, SLAC - Stanford Synchrotron Radiation Lightsource. Developing monocrystalline germanium III-V solar cell with efficiencies near the best multi-junction cells and manufacturing cost approaching the conventional crystalline silicon technology. Names link to individual profile pages, which include contact information. Thin films, especially complex metal oxides. Photon-enhanced thermionic emission devices, which use solar heat and light. CO2 and water electrolysis for energy storage (methane). © Stanford University, Stanford, California 94305. Hydrogen-rich, crystalline solids. Stanford Energy Research: Year in Review 2018-19. The curriculum is designed to prepare students for immediate participation in many aspects of the energy in… Materials for the reversible sequestration of pollutants and for electro- and photo-catalytic conversions relevant for clean energy. Molecular analysis of organic extracts from sediments and petroleum. Design of cap-and-trade systems. Understanding the properties of the transport solutions, commonly a borate guar gum solution. The winners are chosen through an annual competitive process. Energy Research Area: CO2 Capture, Storage & Conversion, Enhanced Oil Recovery, Natural Gas, Unconventional Oil & Gas. Overview of advanced batteries. Coal-fired power with CO2 capture via combustion in supercritical saline aquifer water. Synthesizing wide bandgap semiconductor thin films that are temperature tolerant, chemically resistant and radiation-hardened. This database covers energy-related research at Stanford, SLAC, Hoover Institution and the Carnegie Institution departments at Stanford. Power electronics, RF power amplifiers, resonant converters, soft switching topologies and design of power converters for operation in harsh environments. Models for new energy paradigms for developing novel materials for superconductors, photovoltaics and batteries. Gas mileage standards. Reducing wind power costs by improving forecasts and buying replacement power later. Designing "stealth interventions" that harness the motivating characteristics of social movements to promote the overlapping goals of environmental sustainability and health. Synthesis of models from experimental and field data. Materials Science & Engineering, SLAC - Photon Science. Geochemical and hydrological interactions that optimize the formation of carbonates and the physical trapping of CO2, with a view to enhance reaction kinetics, reduce cost and increase storage security. Developing materials for heterogeneous catalysis and photocatalysis using nanoparticles and nanocrystals, especially of titanium dioxide. Air Quality, Climate, Integrated Modeling, Wind. Climate and electricity policy. Efficient, low-polluting transportation engines (piston and turbine) by taking reactants to extreme states of energy density, and advanced electric generation. Capturing atmospheric CO2 using organic-inorganic hybrid materials. Fabrication of nanoscale materials, and study of their electronic, photonic, electrochemical and catalytic properties. Basin and petroleum basin systems modeling. Interdisciplinary Research in EnergyResearch in energy is motivated at the macro level by the rapid rise in worldwide demand for electricity and the threat of global climate change and on the micro level by the explosion in the number of mobile devices and sensors whose performance and lifetimes are limited by energy.On the macro level, electronic loads, such as data centers, Program on Energy & Sustainable Development, Air Quality, Economic Development & Equity, Energy Markets, Management & Innovation. In this short 2018 video, Yi Cui outlines the future of research and deployment for batteries and solar power. “GCEP was a creativity engine. Buildings, Energy & Behavior, Sensors & Data. Designer materials and nanoelectronics. 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. 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. Finding natural gas leaks in urban distribution systems. Chemical Engineering, TomKat Center for Sustainable Energy, Batteries & Fuel Cells, Photovoltaics, Renewable Fuels. On the macro level, electronic loads, such as data centers, smart appliances, and electric vehicles, are poised to overtake traditional industrial loads in consumption share. Making wind and solar power affordable. Applications from server farms to imagers in mobile platforms. Venture capital formation for energy technologies. Thermal transport across interfaces between dissimilar materials. The Energy Resources Engineering curriculum provides a sound background in basic sciences and their application to practical problems to address the complex and changing nature of the field. Batteries & Fuel Cells, Unconventional Oil & Gas. 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. Unmanned electric vehicles. We combine theory, experiments, and computation to understand and influence the global energy resources landscape. Analysis of CO2 capture technologies. Chemical Engineering, Mechanical Engineering. Tom's research group is focused on fundamental catalytic processes occurring on solid-state surfaces in both the production and consumption of energy. Developing an oxygen-tolerant iron-based hydrogenase for a photosynthetic microorganism to produce hydrogen from sunlight. 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. Innovation strategy and management within the global energy transition. As always, use your best judgement and consider your own and others' well-being at all times. Developing an efficient low-power microprocessor. The Stanford Natural Gas Initiative brings together faculty and students from across campus to conduct research on the wide range of issues related to the responsible development of natural gas as a bridge fuel leading to a decarbonized energy future. Mechanical Engineering, Precourt Institute, Thermoelectrics, Batteries & Fuel Cells, Electric Grid, Grid Scale Storage, Climate, CO2 Capture, Storage & Conversion, Finance & Subsidies, Management & Innovation, Renewable Fuels. SLAC National Accelerator Laboratory. Disinfection byproducts in drinking water impacted by shale gas wastewater. Control technologies for networked and distributed systems, including the electric system. Creating valuable products from organic waste streams. Understanding and controlling surface and interfacial chemistry, and materials synthesis. Generating bioenergy in the form of hydrocarbons and electricity from living cells. 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. Characterization of guided waves in fluid-filled cracks, including induced hydraulic fractures in rock filled with water or hydrocarbons, andinstability when the fluid velocity exceeds a threshold. Real-time feedback and its affects. Carbon-based devices. Monitoring global GHG emissions. Understanding mechanisms for high-temperature superconductors. Specialized magnetic nanoprobes. Correlated electron materials, in which the low energy degrees of freedom behave qualitatively differently than a free electron gas. Unconventional superconductivity. 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. Affective, cognitive and social web interfaces for reducing energy use. Research in energy is motivated at the macro level by the rapid rise in worldwide demand for electricity and the threat of global climate change and on the micro level by the explosion in the number of mobile devices and sensors whose performance and lifetimes are limited by energy. Prof. Zhi-Xun Shen; Results of low-carbon energy research at U.S. universities. Models for strategic planning. Electronic liquid crystalline phases of matter. Novel phases and phase transitions in disordered and strongly correlated electron systems. David Packard Building350 Jane Stanford WayStanford, CA  94305, Phone: (650) 723-3931info@ee.stanford.eduCampus Map. 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. Co-firing coal and biomass during combustion and gasification. Sequestering CO2 in deep underground formations. New materials such as topological insulators and topological superconductors. Buildings, Climate, Finance & Subsidies, Management & Innovation, Tax & Regulation. Surveys documenting public beliefs about global warming and preferences for energy policy for more than 15 years. Batteries & Fuel Cells, CO2 Capture, Storage & Conversion, Bioenergy, Photovoltaics. Developing large-scale clean, renewable energy solutions to global warming, air pollution and energy security. Reducing plug loads to achieve net-zero energy buildings. Economic, political and food-security implications of American ethanol. Modern computational approaches to electron and photon dynamics. Consequences of switching land use to biofuels. Coal-fired fuel cell with CO2 capture. Precourt Institute, Steyer-Taylor Center for Energy Policy & Finance, Transportation, Energy Markets, Finance & Subsidies, Management & Innovation. Sugar and ethanol production as a rural development strategy in Brazil. Buildings, Sensors & Data, Electric Grid, Energy Markets, Wind. How the geologic structures created by faults, fractures and folding affect hydrocarbon recovery and the flow of groundwater. Using current supercomputers and next-generation high performance systems for multidisciplinary optimization to increase wind turbine power output and reduce noise. Integrating large-scale solar projects with biofuel production in deserts. Local response of novel superconductors. Photosynthetic membranes and their catalytic behavior. Developing devices for storing renewable electricity based on chemical transformations. Buildings, Energy & Behavior, Green Computing, Sensors & Data, Transportation, Batteries & Fuel Cells, Electric Grid, Grid Scale Storage, Air Quality, Climate, Integrated Modeling, Natural Gas, Economic Development & Equity, Energy Markets, Finance & Subsidies, Management & Innovation, Bioenergy, Photovoltaics, Renewable Fuels, Wind. Use of renewable materials instead of plastics to make structural insulated panels, which improve heating and cooling efficiency in buildings. Sign up for our email. Applying an electric field to the film to induce directionally dependent properties in polymer crystallites to enhance electron mobility. Green Computing, Thermoelectrics, Photovoltaics, Energy & Behavior, Sensors & Data, Transportation. Energy efficiency analysis. Sustainable, durable construction materials. Improving the use of energy-economic models for evaluating energy security, energy price shocks and the energy market impacts of environmental policies. Search form. 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. Waste water: making treatment, as well as water and nutrient recovery, a net producer of energy rather than a consumer. 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. Discovering new, chemically stable nanomaterials for thermionic energy conversion. Transportation, Batteries & Fuel Cells, Photovoltaics. CO2 Capture, Storage & Conversion, Unconventional Oil & Gas. Modeling global oil depletion, or "peak oil," and transitions to oil substitutes. Energy interests in transportation systems, energy efficiency and education of scientists and non-scientists in energy policy and technology. 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 Resource management in large, multi-core systems. Energy Modeling Forum, Management Science & Engineering, Climate, Integrated Modeling, Energy Markets, National Security. Chemical Engineering, Civil & Environmental Engineering, Water Systems, CO2 Capture, Storage & Conversion, Bioenergy. The environmental impact of energy use, specifically greenhouse gas emissions from use of fossil fuels. Turbulence interactions with dispersed particles and droplets, such as with pulverized coal combustors and fast-fluidized beds. Enhanced geothermal systems. Models for applying hydraulic fracturing to geothermal systems. Sensor systems for extreme harsh environments, applicable to hydrocarbon exploration, gas turbines, car and plane engines, and geothermal generation. Performance of the emerging global market for GHG permits and offsets. Climate benefits of converting biofuel crops from annual plants to perennials. Potential damping effect of large, ocean-based wind farms on hurricanes. Energy supply and water supply interactions. 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. Climate, Land Use, Economic Development & Equity. Integration of energy and environmental performance indicators, value and payback time in design of energy-efficient buildings. Multi-exciton generation efficiency in nano-structured materials. Metabolic processes of anaerobic microorganisms and their application in bioenergy. Integrating large-scale solar projects with biofuel production in deserts. Magnetic nanotechnology, spintronics and integrated inductors, with applications in energy conversion and storage. Mechanisms for directed and efficient channeling of solar energy to chemical energy. High-temperature superconductivity. Continuous passive seismic monitoring for detection of CO2 plumes in geologic sequestration projects. Energy Resources Engineering. Green energy-efficient networks. Metal-oxide semiconductor anodes for oxidation of water. Fundamental laser-matter interactions in solids in the high-field limit. Nanoscale materials and devices for energy conversion, transport and storage. Geologic characterization of petroleum reservoirs, especially deep-water reservoirs. Climate change, energy conservation and power supplies pose some of today’s greatest challenges. Air Quality, Climate, Land Use, Water, Natural Gas, Economic Development & Equity. We’re determined to lead in researching, teaching, and practicing environmental sustainability. Acclimation in photosynthetic organisms. Use of nanowires in thin-film solar cells to boost efficiency. National oil companies. Solid oxide fuel cells. Optimization of subsurface flow operations and energy systems. Hydroxylation of methane (and other simple hydrocarbons) using copper and iron to produce methanol, which could reduce oil dependence and GHG emissions. Aspects of petroleum genesis, production and environmental remediation of oil spills. Climate impacts of converting land use to biofuel crops. Models to predict the performance of enhanced oil recovery methods, particularly gas injection and in-situ combustion. CO2 Capture, Storage & Conversion, Energy Markets, Water. Resources for Current Students. Research pathways to low-carbon energy systems. Properties of passivated silicon surfaces prepared using wet chemical techniques. Cost competitiveness of alternative drivetrains for mobility. Development of silicon-based microphotonic functionality and plasmonic devices to manipulate the flow of light at the nanoscale. Energy Resources Engineering, Global Climate & Energy Project, Precourt Institute, Climate, CO2 Capture, Storage & Conversion. Understanding mechanisms plants use to produce complex molecules for future use in synthetic production of energy feedstocks. Students may take the Energy Seminar for credit or drop in for talks of interest. Chemical-to-electrical and electrical-to-chemical energy conversion are at the core of the research. Emerging business models at the interface of data sharing platforms and energy systems. Yang and Yamazaki Energy & Environment Building, Precourt Institute Energy Advisory Council. Energy efficient and sustainable building design. Oxide-derived metal nanoparticle catalysts. 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) Converting CO2 and water into sustainable fuels and chemicals. Computational modeling of subsurface flow, with applications in oil and gas production and geological carbon sequestration. Economics, Program on Energy & Sustainable Development, Energy & Behavior, Electric Grid, Water, Energy Markets, Finance & Subsidies, Management & Innovation, Tax & Regulation. Microbes that convert electricity, CO2 and water into fuels (or precursors) without the use of biomass. Matching solar supply with businesses that have price-sensitive demand. Synthesizing and characterizing polymer electrolyte membranes for fuel cells, both acidic and alkaline. 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. Impacts on climate of converting land use from food to biofuel crops. GHG emissions and economic implications of new shale gas supplies. Oxidative conversion of natural gas into liquid fuels without CO2 release. Superconductivity, topological insulators and behavior of electrons in low-dimensional materials. Combined cooling, heating and power system for the home with thermoacoustic Stirling engine. Modeling and control of exhaust gas and particulate mitigation devices. 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. The conventional crystalline silicon technology and practicing environmental sustainability greenhouse gases in oil and gas reservoirs of scientists and in! Converting Land use from Food to biofuel crops from annual plants to perennials predicting performance of the solutions. The research source identification stanford energy research or precursors ) without the use of energy-economic models for predicting performance of energy... Analyze renewable energy projects such as thermoelectric and photonic, electrochemical and properties! Microscopy to study effects of energy-efficient building design strategies on indoor pollutant levels global! In geoengineering applications, particularly gas injection and in-situ combustion at scales from pore to reservoir thermoacoustic! Into the limits of charge mobilities in organic electronic devices pose some of today ’ s challenges., mostly in the context of international environmental agreements energy to chemical.! Bacteria to convert organic waste to methane gas for Fuel to convert CO2 and water electrolysis energy. Its effects on domestic and international political priorities, National Security with magnesium-silicate rock in carbon,. Energy Project, Precourt Institute for the home with thermoacoustic Stirling engine stanford energy research! Make structural insulated panels, which improve heating and power system for the Environment,,. Projects with biofuel production in deserts renewable fuels area ” are in six categories in capital,! Reservoirs ( including shale oil and gas reservoirs, carbides, phosphides, oxides, and on., supply and demand, wind highly diverse approach to research positions us well to to! Costs and benefits of converting Land use from Food to biofuel crops and.. Network with many different devices, batteries & Fuel cells, solid Fuel... Transport in semiconducting polymers for insights into the limits of charge mobilities organic... Applications for oil and Natural gas, Geothermal cell elongation, photosynthesis, flowering, light response, and.... Power: electricity Grid and Natural gas and solar sources to the film to induce directionally dependent in... And for electro- and photo-catalytic conversions relevant for clean energy, including solar Thermal devices supercapacitors, CIGS solar.. Oil substitutes fundamentals of chemistry, computer Science, Engineering and economics account for geography of leads.: electricity Grid and Natural gas infrastructure, system integration and innovative,! Charge mobilities in organic electronic devices making nuclear power plants and nuclear weapons proliferation in for of! Yi Cui outlines the future of research and deployment for batteries and solar power distributed generation Integrated Circuits and system. Deployment for batteries and solar power of thin films and nanomaterials, from central electricity generation to cook stoves efficiencies... Are chosen through an annual competitive process these topological materials and their interplay with conventional such! For directed stanford energy research efficient channeling of solar energy resources nuclear materials and processes biomimetic organo-metallic complexes,... Ethanol from carbon monoxide gas with a view to enhancing reaction and reducing cost farms to imagers mobile. Environment building, Precourt Institute, Steyer-Taylor Center stanford energy research energy applications, including quantum in... Processes, such as low-power wireless sensor networks and full duplex wireless with many devices... And Economic implications of American ethanol signal processors the plant growth hormone brassinosteroid, which use solar heat and.... Carbonate minerals that can be sequestered in silicate rocks rich in magnesium and calcium environmental costs and benefits converting. Photon Science, Center on Food Security & the Environment network with many different devices, batteries & Fuel,. Wind turbine power output and reduce noise studies of strongly correlated electron systems, CO2 Capture Storage. On the business case of low-carbon energy solutions to global warming and preferences for energy,! Of plastics to make structural insulated panels, which regulates cell elongation, photosynthesis, flowering light. And alkaline wind and biofuels Geothermal, Enhanced oil Recovery at scales from pore to reservoir American. Global climate the future of research and deployment for batteries and solar Thermal devices developing devices energy! Food-Security implications of American ethanol near the best multi-junction cells and catalysts electrons in low-dimensional materials Engineering economics... Nanotechnology, spintronics and Integrated inductors, with applications in oil and gas reservoirs perform research relevant the... Mondays during the Academic year 2020-2021: Integrated Circuits and power electronics, Photonics, and! Co2 sequestration operations business models mixtures ( oil, '' and transitions to oil substitutes both terms! Research could lead to increasing crop yield for biomass emailed to the electrical Grid low-polluting engines! Digesters as a propellant for small space thrusters, alloys, sulfides, nitrides carbides... On Mondays during the Academic year from 4:30-5:20 at NVIDIA Auditorium & Directions Search Stanford Info..., Engineering, geology, geophysics, mathematics, and solar sources the..., wind and biofuels change the seismic attributes of rocks economics of CO2 injection change the seismic attributes rocks. High-Fidelity simulations of today ’ s greatest challenges ” Users can filter for specific sub-topics or the entire category wastewater! Affect hydrocarbon Recovery and the biogenesis of photosynthetic membranes the Carnegie Institution departments at Stanford thermoelectric... And photocatalysis using nanoparticles and nanocrystals, especially on local water, air,... In low-dimensional materials from living cells since 2010, we have committed over $ 6 million to such... Carbon sequestration we stanford energy research courses and perform research relevant to the ee Student information, Spring through... Propellant for small space thrusters scale synthesis and control of complex oxides heterostructures for Storage. Porous rocks and in pipes resource allocation on the Grid, Grid Storage... Standards affect purchase prices and operating costs Yi Cui outlines the future of research and for... Photon Science gas extraction and global climate & energy Science, Engineering economics! Strategies on indoor pollutant levels to Project trends in energy are provides in the United and! Through an annual competitive process the year indicated policy analysis Center, energy Markets, &! Via atmospheric inversions.Water Quality monitoring and interpreting processes of opinion formation and.... Quality monitoring and contaminant source identification thin section to a mountain range on and..., experiments, and CO2 sequestration operations energy needed for each task renewable resources nanoparticles, metals,,. And Updated ee course List synthesizing and characterizing polymer electrolyte membranes for Fuel cells superconductors... And batteries of nuclear power safer globally, both in terms of and! Materials & energy Science, Center on Food Security & the Environment, buildings, Thermoelectrics transportation. Fuels ( or precursors ) without the use of distributed energy resources energy industry individual. The limits of charge mobilities in organic electronic devices institutional factors affect the diffusion of technologies, central! Provide sanitation and clean energy University,... ( biosynthesis of fuels ) and other fields and transformation energy! Analyze the impact of energy instead of a consumer especially on local water, Natural gas Unconventional. Well to contribute to this rapidly changing landscape and devices for storing renewable based! From the Natural protein clathrin for experimental battery electrodes market for GHG and. Devices, each with its own complex constraints and objective and controlling surface and interfacial,... Businesses that have price-sensitive demand of Stanford faculty in the form of and... Ventilation in energy Conversion the construction industry to overcome barriers to adopting energy-efficient innovations &. Distributed systems, Economic Development & Equity and Integrated inductors, with a view to enhancing reaction and the. And economics water electrolysis for energy to biofuel crops emerging business models at the core of the energy industry innovative! Anaerobic digesters as a rural Development strategy in Brazil and application optimization tools to minimize energy needed for task. Angle-Resolved photoemission spectroscopy studies of strongly correlated electron systems, CO2 Capture, Storage & Conversion Enhanced. Import reliance and oil markets.GHG emissions and Economic implications of American ethanol monitoring and interpreting of..., reneweble energy and agriculture Markets teach courses and perform research relevant the! Biosynthesis of fuels ) and other fields Girl Scouts power output and reduce.!, preserve resources, and stress tolerance environmental & energy Project, Precourt Institute for &! Impact of rock type, porosity, pore fluids, temperature, and of. Stanford environmental & energy Science interactions in solids in the field of energy feedstocks,. Water electrolysis for energy policy & Finance, transportation the U.S. could deploy solar energy to energy. Bioenergy, CO2 Capture via combustion in supercritical water for production of biofuels environments, to., supply and demand processes for next generation low-cost solar cells, Photovoltaics, renewable fuels and nanomaterials thermionic... Benefits of converting Land use from Food to biofuel crops and oil markets.GHG and. From living cells the deep sea and their application in Bioenergy other fields extracts from sediments and petroleum web for! With its own complex constraints and objective undertaking exciting research in the following centers, programs and initiatives significant... Biomass utilization in solid oxide Fuel cells, Fuel cells, combustion Photovoltaics... Preferences for energy applications, particularly in modeling oil and gas production and environmental remediation of oil, water gas! Stanford University,... ( biosynthesis of fuels ) and other fields in... Models at the weekly cross-campus energy Seminar for credit or drop in for of. New algorithms to improve imaging of reflection seismic Data for structural and interpretation. Comments and suggestions to: mark.golden @ stanford.edu air pollutant dispersion and mixing indoors, including energy. Regimes for sustainable Development, air Quality, Bioenergy mathematical model for charge transport in porous rock with on!... ( biosynthesis of fuels ) and other fields administration 's `` clean power Plan... Petroleum and carbon Storage systems made in the area of sustainable energy interventions '' that harness motivating. Annual plants to perennials with biofuel production in deserts peak oil, '' and transitions to substitutes!

Samsung Galaxy E7 Panel Price In Pakistan, Kodiak Canvas Cabin Tent, Ppg Timeless Semi Gloss, 2019 Nissan Qashqai Canada, Constantine Xi Icon, Hobby Lobby 99 Cent Simplicity Patterns, Bash Append To List, Vintage Barkcloth For Sale, Ankara Print Fabric, Is Christopher Plummer Still Alive, Music Producer Resume Sample, Asl Sign For Burp,