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Researchers at Harvard have demonstrated a metal-free organic–inorganic aqueous flow battery—a quinone–bromide flow battery (QBFB)—as an example of a class of energy storage materials that exploits the favorable chemical and electrochemical properties of a family of molecules known as quinones.
Start-up Calysta Energy plans to use methane as a feedstock for engineered organisms to produce liquid hydrocarbon fuels and high value chemicals that are cost-effective, scalable and reduce environmental impact. Conversion method. Click to enlarge. Comparison of biofuel platform efficiency (source: Calysta Energy). ProteinGPS.
Under the FOCUS program, projects will develop advanced solar converters that turn sunlight into electricity for immediate use, while also producing heat that can be stored at lowcost for later use as well as innovative storage systems that accept both heat and electricity from variable solar sources. Lead organization.
University of Colorado Boulder researchers have developed nanobio-hybrid organisms capable of using airborne carbon dioxide and nitrogen to produce a variety of plastics and fuels, a promising first step toward low-cost carbon sequestration and eco-friendly manufacturing for chemicals. —Prashant Nagpal.
Researchers in China have developed a nitroaromatic cathode that performs a six-electron reaction per nitro group, significantly improving the specific capacity and energy density compared with organic electrodes based on single-electron reactions. 1, which surpass all existing organic cathodes. 1 and energy density of 3,273 Wh?kg
The new material is simple to make, requiring primarily off-the-shelf melamine powder—which today costs about $40 per ton—along with formaldehyde and cyanuric acid, a chemical that, among other uses, is added with chlorine to swimming pools. The lowcost of porous melamine means that the material could be deployed widely.
The EU’s DirectFuel project, which launched on 1 October, intends to develop a photobiological process for the direct conversion of sunlight and CO 2 into engine- and infrastructure-ready transport fuels such as propane. The 4-year project will have funding of up to €3.73 million (US$5.1 PCC 6803, a freshwater cyanobacterium.
The UGA research group engineered a synthetic pathway into the organism, introducing genes from other anaerobic bacterium that produce ethanol, and constructed a pathway in the organism to produce ethanol directly. Westpheling spent two and a half years developing genetic methods for manipulating the C. Whereas wild-type C. 1402210111.
DE-FOA-0002423 ) Topic Areas ins the FOA support DOE’s Bioenergy Technologies Office’s (BETO’s) objectives to reduce the minimum selling price of drop-in biofuels, lower the cost of biopower, and enable high-value products from biomass or waste resources. Development of novel methods for rapid/real-time measurements.
At the hubs, which can be built at or near landfills, Raven SR will convert mixed and multiple organic wastes, including municipal solid waste, greenwaste, food waste, medical, paper, etc. into locally produced, renewable hydrogen for Hyzon’s fleet of zero-emission commercial vehicles.
One program, Reducing Emissions using Methanotrophic Organisms for Transportation Energy (REMOTE, earlier post ), provides $34 million to 15 projects to find advanced biocatalyst technologies that can convert natural gas to liquid fuel for transportation. process intensification approaches for biological methane conversion.
The US Energy Department’s Advanced Research Projects Agency-Energy (ARPA-E) has selected 14 projects for $27 million in funding to support the development of next-generation power conversion devices. Lead organization. High Quality, Low-Cost GaN Single Crystal Substrates for High Power Devices. Earlier post.).
Bisabolene is a chemical precursor to bisabolane—a potential renewable diesel and jet fuel that phase separates readily when released to the fermentation broth, enabling efficient recovery via two-phase extractive fermentation with an organic overlay. —Sundstrom et al.
We ask organizations to move this realistic, conservative, and cost-effective approach to the top of their talking points and priorities. We’re about to enact the “Home Star” and “Building Star” programs—putting people to work on “Cash for Caulkers” retrofits that will make buildings more comfortable and cut owners’ fuel costs.
One area where metabolic engineering has a sizable advantage over synthetic organic chemistry is in the production of natural products, particularly active pharmaceutical ingredients (APIs), some of which are too complex to be chemically synthesized and yet have a value that justifies the cost of developing a genetically engineered microorganism.
Twenty-three of the projects receiving funding are headed by universities, eight are led by the Energy Department’s National Laboratories and one project is run by a non-profit organization. Lead organization. Light-Material Interactions in Energy Conversion (LMI). Solid-State Solar-Thermal Energy Conversion Center (S3TEC).
A team from Saudi Aramco Research and Development Center has developed a novel low-cost, high-octane gasoline blend component it calls SuperButol. Overall single pass conversion is 14 vol%. Unreacted butenes are recycled to the reactor until all the butenes are converted to the isomers of butanols and iso-octane.
The projects conducted through this program are geared toward reducing the cost of coal conversion and mitigating the environmental impacts of fossil-fueled power generation. Lead organization. DOE: $650,000 Non DOE: $162,500 Total: $812,500 (20% cost share). Lead organization. Bio-gasification of Coal to Methane.
Lead organization. Natural Gas Reactor for Remote Chemical Conversion. sunlight through low-cost, plastic light-guiding sheets and then. Turbo-POx For Ultra Low-Cost Gasoline. conversion of natural gas to liquid fuels. combustor of a natural gas turbine, facilitating its conversion into a.
Novel inorganic-organic perovskites for photovoltaics. The mineral perovskite is a promising, low-cost material for enhancing the efficiency of silicon solar cells. efficiency, low-cost silicon solar cells. Maximizing solar-to-fuel conversion efficiency in photo-electrochemical cells. Light trapping in high?efficiency,
The pilot-scale biorefinery projects selected today will use a variety of non-food biomass feedstocks, waste-based materials, and algae in innovative conversion processes. Several organizations are participating in this consortium led by Mercurius Biorefining, including Purdue University, Pacific Northwest National Laboratory, and Incitor.
The US Advanced Research Projects Agency - Energy (ARPA-E) is awarding $33 million to 13 new projects aimed at developing transformational fuel cell technologies for low-cost distributed power generation. Lead organization. Lead organization. Category 1: Intermediate Temperature Fuel Cells for Distributed Generation.
The bioreactor technology is under development for efficient methane-to-liquids fermentation processes, enabling rapid, cost-effective methane conversion into protein, industrial chemicals and fuels. Calysta develops sustainable industrial products using novel natural gas conversion technology using methane. Earlier post.).
The demonstration project will be conducted with the support of New Energy and Industrial Technology Development organization (NEDO) of Japan, under the program of “Development of Technology for Safe, Low-cost, Large-size Battery System.” The storage system is slated to be handed over for operational use in early 2013.
The IDEALFUEL project aims to create sustainable alternatives by developing new efficient and low-cost methods to produce low-sulfur heavy fuel oils from wood-based non-food biomass. Although cleaner fuels are available, many companies opt for HFOs due to their lowcost.
Today’s technologies for making biofuels all rely on photosynthesis—either indirectly by converting plants to fuels or directly by harnessing photosynthetic organisms such as algae. Electrofuels approaches will use organisms able to extract energy from other sources, such as solar-derived electricity or hydrogen or earth-abundant metal ions.
The report, “ Developing New Paradigms for Biofuel Separations to Enable an Alternative Fuels Future ”, was released recently and is intended to serve as a research roadmap that will help address the current issues associated with the thermochemical conversion of biomass. The conversion unit. Biomass conversion unit.
The team will focus on feedstock development, sustainable forest production and establishing new methods to identify the most promising plant lines for biofuel conversion. million to enable the regular production of biomass for economically viable conversion using existing refinery infrastructure.
That includes working with transit agencies and car sharing organizations to increase access to the benefits of electric transportation, especially for those in underserved communities. Active conversations with a wide variety of partners to help achieve this 2030 EV vision.
Lead organization. Lead organization. High Performance, LowCost Superconducting Wires and Coils. for High Power Wind Generators The University of Houston will develop a new, low-cost. American Superconductor will develop a new, low-cost. Lead organization. Description. Description.
Biobutanol processes using Microvi’s technology would benefit from reduced capital and operating costs. The technology will be retrofitable in existing bioethanol processes and work with any microorganism including genetically modified organisms. Microvi’s butanol technology is based on the company’s MicroNiche Engineering platform.
In the joint R&D with NEDO, Nitto Denko will fully leverage its polymer membranes expertise in domains such as seawater desalination and gas/vapor separation to reduce the production cost of bioethanol as well as the energy consumption for its distillation/dehydration.
The patent-pending manufacturing technology mimics low-cost fabrication of commercial Li-ion cells with liquid electrolytes, but instead uses solid state electrolytes with low melting points that are melted and infiltrated into dense electrodes. —Professor Gleb Yushin, corresponding author.
The workshop will bring together thought leaders from distinct science and engineering communities to develop new ideas and identify practical approaches toward increasing the efficiency of light collection by biological systems and the conversion of that energy into liquid forms of chemical energy that can be used for transportation.
Researchers at LS9 have discovered an alkane biosynthesis pathway in cyanobacteria; i.e., a metabolic pathway that produces alkanes—the major hydrocarbon constituents of gasoline, diesel and jet fuel—in a direct, simple conversion from sugar. Schirmer et al.
The listing, which includes 85 organizations as of 22 January, is grouped into 13 categories, with the largest categories being energy storage (29 applicants); biofuels (17); and renewable power (13): Biofuels (17). Neither the Department of Energy nor ARPA-E endorses or sponsors the individuals, organizations and/or technologies identified.
Under the agreement, Genomatica will create proprietary, specially-designed organisms and complete manufacturing processes to efficiently and economically convert syngas into chemical products. Genomatica’s technology complements Waste Management’s advancement of thermo-chemical conversion and fermentation technology platforms.
Milczarek and Inganäs describe how a class of organic compounds known as quinones allows the lignin derivatives to shed a proton and store this electric charge in its place. Charge storage in organic polymers rarely gives energy and power densities, gravimetric or volumetric, that match the needs for secondary batteries and supercapacitors.
ARPA-E requests innovative proposals which can overcome these challenges through the utilization of metabolic engineering and synthetic biological approaches for the efficient conversion of carbon dioxide to liquid transportation fuels. Batteries for Electrical Energy Storage in Transportation (BEEST).
The US Department of Energy (DOE) Advanced Research Projects Agency - Energy (ARPA-E) will award up to $30 million to fund a new program focused on the development of transformational electrochemical technologies to enable low-cost distributed power generation. DE-FOA-0001026 ). Source: ARPA-E. Click to enlarge. Source: ARPA-E.
The Precourt Institute for Energy, the umbrella organization for energy research and education at Stanford, will fund the following four studies: Nanostructured Polymers for High-Performance Batteries. This project explores the use of specially designed nanostructured polymers to make high-energy, low-cost, flexible and stretchable batteries.
Scale-Up of the Primary Conversion Reactor to Generate a Lignin-Derived Cyclohexane Jet Fuel. Microchannel Reactor for Ethanol to n-Butene Conversion. Conversion of 2,3-Butanediol to Biojet Fuel: Scale-up and Technoeconomic Analysis of Energy-Efficient Separations and Fermentative Diol Production. Project title. Federal share.
Funded in part by an $18-million US Department of Energy (DOE) grant and a $4-million grant from the State of Michigan, the API Alpena Biorefinery will demonstrate the conversion of hemicelluloses extracted from woody biomass to fermentable sugars that can be used for production of ethanol.
the developer of a Consolidated Bioprocessing (CBP) platform for low-cost production of cellulosic ethanol using the Q-microbe ( earlier post ), have formed a strategic partnership to accelerate commercialization efforts for industrial-scale cellulosic ethanol production. India-based Praj Industries Limited and Qteros, Inc.,
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