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Biofuels producer Renewable Energy Group joined Iowa State University (ISU) at the BioCentury Research Farm (BCRF) to mark the start of a new hydrotreater pilot plant. REG converts waste and byproduct fats and oils into biodiesel and renewable diesel.
Universal Hydrogen ( earlier post ) has signed LOIs with Icelandair Group (Iceland), Air Nostrum (Spain), and Ravn Air (Alaska) for aftermarket conversion of aircraft to hydrogen propulsion and for the supply of green hydrogen fuel using Universal Hydrogen’s modular capsules. Icelandair. Icelandair.
in close collaboration with GTI and The University of Texas at Austin, has launched a US Department of Energy project, Demonstration and Framework for H2@Scale in Texas and Beyond. The project is supported by DOE’s Hydrogen and Fuel Cell Technologies Office within the Office of Energy Efficiency and Renewable Energy.
Ricardo has developed a hydrogen-fueled research engine which could offer a renewable, economic and durable technology solution to accelerate zero-carbon emissions in heavy duty trucks, off-highway machines and marine vessels. —Adrian Greaney, Director of Technology and Digital at Ricardo Automotive and Industrial EMEA Division.
While there is global potential to generate renewable energy at costs already competitive with fossil fuels, a means of storing and transporting this energy at a very large scale is a roadblock to large-scale investment, development and deployment. Generation 2 moves the Haber-Bosch process to renewable sources of hydrogen.
Researchers from the Chinese Academy of Sciences and Tsinghua University have used a gallium, indium, tin and bismuth alloy to generate hydrogen, when placed in contact with an aluminum plate immersed in water. An open-access paper on their work appears in the Journal of Renewable and Sustainable Energy , from AIP Publishing.
The investment is the biggest milestone to date of Cepsa’s Positive Motion energy transition plan to lead sustainable mobility and the production of green hydrogen and advanced biofuels in Spain and Portugal this decade. Andalusia has everything it takes to become one of the most competitive regions in the world for hydrogen production.
million) to five demonstration phase projects for low-carbon hydrogen production. The project concerns the production of hydrogen at scale from offshore floating wind in deep water locations. The company will also develop further plans for large scale production of electrolyzers. Led by Cranfield University.
Auburn University researchers are leading a $2-million US Department of Energy Co-Optima project ( earlier post ) that will evaluate renewable butyl acetate (BA) as a bio-based fuel additive that can be blended with diesel fuel to reduce soot and greenhouse gas emissions and yield cleaner engine operation in cold-weather conditions.
Researchers from Japan’s NIMS (National Institute for Materials Science), the University of Tokyo and Hiroshima University have jointly conducted a techno-economic analysis for hydrogen production from photovoltaic power generation (PV) utilizing a battery-assisted electrolyzer. Credit: NIMS. 2018.11.119 ).
Utilization of renewable solar energy is crucial for addressing the global energy and environmental concerns and achieving sustainable development. Kazunari Domen from The University of Tokyo, Prof. Lianzhou Wang from The University of Queensland, Prof. Credit: DICP. 2021.01.001.
Global renewable energy investment increased between 2013 and 2018, reaching its peak at US$351 billion in 2017, according to a new report by the International Renewable Energy Agency (IRENA) and Climate Policy Initiative (CPI). Renewable energy investment slightly declined in 2018, with modest growth through 2019.
Researchers at Monash University in Australia have conducted a lifecycle analysis and net energy analysis (LCA/NEA) of a hypothetical large-scale solar-electrolysis plant for the production of green hydrogen. of hydrogen is currently produced via water electrolysis and only a fraction of this production is powered by renewable energy.
SunHydrogen , the developer of a technology to produce renewable hydrogen using sunlight and water, has extended its sponsored research agreement with the University of Iowa through 31 August 2020. As we are set to begin the production phase of our GEN 1 hydrogen panels, our research efforts will become increasingly focused on GEN 2.
Researchers at the University of Melbourne (Australia) have demonstrated a method of direct hydrogen production from air— in situ capture of freshwater from the atmosphere using hygroscopic electrolyte and subsequent electrolysis powered by solar or wind with a current density up to 574 mA cm ?2. —Guo et al. Zavabeti, A.
Bloom Energy, a developer of solid oxide fuel cell power generators, announced the ability of its Energy Servers to operate on renewable hydrogen. At peak times, some US states and countries already have more renewable power than their grids can handle.
Siemens Energy, Duke Energy and Clemson University have teamed up to study the use of hydrogen for energy storage and as a low- or no-carbon fuel source to produce energy at Duke Energy’s combined heat and power plant located at Clemson University in South Carolina.
Researchers from Newcastle University in the UK have engineered Escherichia coli bacteria to capture carbon dioxide using hydrogen gas to convert it into formic acid. coli host strain was engineered for the continuous production of formic acid from H 2 and CO 2 during bacterial growth in a pressurised batch bioreactor. 00299-21.
Researchers at the University of Turku in Finland have developed a thin-layer artificial biofilm technology for sustainable and long-term ethylene photoproduction. The team optimized the production system by varying different parameters, such as radiance, inorganic carbon level, and periodicity of medium renewal.
A team at Sandia National Laboratories has designed a five-component gasoline-like blend containing 40% vol of a mixture of 2-methyl furan and 2,5-dimethyl furan (representative of products of a viable pathway to make furans from bio-feedstock). Simulations show promising results when the resulting fuel is compared to regular E10 gasoline.
The University of British Columbia’s (UBC) Advanced Materials for Energy Storage Lab, under the leadership of Dr. Jian Liu, is the project’s research lead during the initial stages. Eagle Graphite owns and operates one of only two flake graphite production facilities in Canada and the only graphite quarry in western North America.
A consortium comprising Engie Solutions, Siemens Gas and Power, Centrax, Arttic, German Aerospace Center (DLR) and four European universities is implementing the HYFLEXPOWER project funded by the European Commission under the Horizon 2020 Framework Program for Research and Innovation (Grant Agreement 884229).
In February 2022, GTI Energy, S&P Global Commodity Insights and the National Energy Technology Laboratory (NETL) launched the Open Hydrogen Initiative (OHI), a collaboration to further transparency into the environmental impact of hydrogen production and help unlock its full potential as an important driver of energy transitions.
Many biofuels, including ethanol, biodiesel and other products derived from organic material (biomass), are almost exclusively produced via fermentation. Carbon-Negative Chemical Production Platform - $4,160,262.57. National Renewable Energy Laboratory. University of Wisconsin-Madison. The awardees are: LanzaTech, Inc.
Power Systems business unit signs letter of intent for the construction of a demonstration plant for the production of synthetic fuels Schell: “We will be electrifying the entire system, including the fuel” Important step towards sector coupling and decarbonising propulsion systems and power generation.
Partners from Germany and Finland in the SOLETAIR project are building a compact pilot plant for the production of gasoline, diesel and kerosene from solar energy, regenerative hydrogen and carbon dioxide. An electrolysis unit developed by Lappeenranta University of Technology (LUT) produces the required hydrogen by means of solar power.
Danish Minister for Transport Trine Bramsen, Aalborg municipal government representatives, and European media were invited to witness the first test runs of Geely methanol vehicles on Danish roads and visit the e-methanol production facility at Aalborg University.
The EU-funded research project HyFlexFuel recently successfully produced biocrudes via hydrothermal liquefaction (HTL) from a variety of biomasses, including sewage sludge, food waste, manure, wheat straw, corn stover, pine sawdust, miscanthus and microalgae in a pilot-scale continuous HTL plant at Aarhus University (Denmark).
A study from the University of Exeter analysed the impacts of the low-carbon transition in power, transport and heating on UK productivity. The post University of Exeter study details how the green energy transition will boost UK productivity appeared first on Innovation News Network.
In an open access paper published in Nature Communications , researchers from the University of Wollongong in Australia report that their capillary-fed electrolysis cell demonstrates water electrolysis performance exceeding commercial electrolysis cells, with a cell voltage at 0.5 2 and 85 °C of only 1.51 kWh/kg hydrogen (vs. Hoang, A.L.,
Huge and immediate need for renewable-based fuels in shipping represents opportunity for investors, according to ‘Fuelling the Fourth Propulsion Revolution’ report released today. Particular opportunity for the Global South identified as net-zero fuel production costs expected to be up to 20% lower in Latin America and Africa.
Researchers from the University of Birmingham have designed a novel adaptation for existing blast furnaces that could reduce CO 2 emissions from the steelmaking industry by nearly 90%. According to the International Renewable Energy Agency (IRENA), it must achieve a 90% reduction in emissions by 2050 to limit global warming to 1.5°C.
The electrocatalytic conversion of CO 2 using renewable energy could establish a climate-neutral, artificial carbon cycle. Excess energy produced by photovoltaics and wind energy could be stored through the electrocatalytic production of fuels from CO 2. In contrast, pure copper foil produces C 1 products but hardly any C 2+ products.
OXCCU, a company spun-out from the University of Oxford in 2021 that is focused on converting carbon dioxide and hydrogen into industrial and consumer products ( earlier post ), completed an £18-million (US$22.8 million) Series A financing round.
A team of Brown University researchers has fine-tuned a copper catalyst to produce complex hydrocarbons—C 2+ products—from CO 2 with high efficiency. The electrochemical CO 2 reduction reaction (CO 2 RR), driven by renewable energy, is a promising strategy to reduce CO 2 accumulation. —Kim and Palmore (2020).
As part of DOE’s Plastics Innovation Challenge, these projects will also help improve existing recycling processes that break plastics into chemical building blocks, which can then be used to make new products. Partners include Algenesis, BASF, Pepsi, Reef, and University of California – Davis.
Researchers in China led by a team from Fudan University have demonstrated the electrochemical reduction of CO 2 toward C 2+ alcohols with a faradaic efficiency of ~70% using copper (Cu) catalysts with stepped sites. C 2+ alcohols are desirable due to their high energy densities and large global market capacities.
Researchers from the Technical University of Denmark and Haldor Topsoe, with colleagues from the Danish Technological Institute and Sintex have developed a “ disruptive approach to a fundamental process ” by integrating an electrically heated catalytic structure directly into a steam-methane–reforming (SMR) reactor for hydrogen production.
Electrolytic hydrogen production powered by renewable energy is seen as an environmentally friendly means to ameliorate global climate and energy problems. The material can be used as either an anode or a cathode, and demonstrates high activity and stability in the production of hydrogen and oxygen in the electrolysis of water.
Ben Wiley, a professor of chemistry at Duke University and his team are investigating how nano- and microstructured porous electrodes can improve the productivity of hydrogen generation in a zero-gap, flow-through alkaline water electrolyzer. Wiley Lab, Duke University). Inset: Electron microscope view of the felt.
A team at the University of Tokyo has demonstrated steam electrolysis using a solid acid electrolysis cell (SAEC) for the production of hydrogen. The SAEC used a CsH 2 PO 4 /SiP 2 O 7 composite electrolyte and Pt/C electrodes; hydrogen production was successfully demonstrated with Faraday efficiencies around 80%. Fujiwara, N.,
Renewable hydrogen systems manufacturer Ways2H Inc. announced the completion of a facility in Tokyo that will convert sewage sludge into renewable hydrogen fuel for fuel cell mobility and power generation. A new facility in Tokyo that will convert sewage sludge into renewable hydrogen gas for fuel-cell vehicles is nearing completion.
The US Department of Energy (DOE) will award $590 million to renew its four existing Bioenergy Research Centers (BRCs). Each of the four centers, led by a National Laboratory or University, support the science behind a bio-based economy and aims to break down the barriers to building a strong domestic bioenergy industry.
University of Queensland researchers, working in collaboration with the Technical University of Munich (TUM), have found a way to convert sugarcane into isobutanol— a building block of aviation fuel and other products—more efficiently. An open-access paper on the work is published in Chemistry - a European Journal.
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