Researchers at the ETH Zürich have devised a novel way to use abundantly available #iron to #store #hydrogen. In three stainless steel walled containers, just six millimeters thick walls, the researchers demonstrated hydrogen storage of 10 MWh for months without losing storage capacity. Energy storage and retrieval happens thanks to the commonly occurring process of iron rusting, a principle also used in iron-air batteries. In a bid to reduce its dependence on fossil fuels, the Swiss government plans to use solar energy to source 40 percent of its energy needs by 2050. The problem with solar energy, especially in Switzerland, is that there is too much of it in summer and too little in winter when energy demand shoots up. To overcome this shortcoming, the government plans to use energy from wind and hydro farms but also gas-fired plants when required. Researchers at ETH Zurich, however, have a better idea and think hydrogen could meet this need. Hydrogen gas can be made by splitting water using #solarenergy during summer months and used as a clean fuel in winter. But, storing this highly volatile and flammable gas over long periods is energy-intensive and comes with many risks. The safer and much cheaper solution is to store it as rust Led by Wendelin Stark, a professor of functional materials ETH Zurich researchers use the steam-iron process, known since the 19th century to store hydrogen in iron. The flammable gas is pumped into a stainless steel reactor, where iron ore is maintained at 400 degrees Celsius At these temperatures, hydrogen extracts oxygen from iron oxide or rust, making water and iron. This is much like charging a battery, where energy is stored in water and iron and can be retained for months without major losses In winter months when energy demand is high, researchers can run hot steam into these reactors. This reverses the process forming rust and releasing hydrogen gas. The hydrogen can be used to generate electricity in a fuel cell or even burned as fuel to move a turbine Schematic representation of conversion processes involved in storing hydrogen in iron The greatest advantage of this storage option is that it is easy to execute and inexpensive. The materials used in the process do not need any preprocessing, and they can be easily scaled anywhere in the world without pumping up market prices of iron Onsite storage capacities can be increased by simply adding more reactors, and the material can be recycled through charge-discharge cycles for years without requiring replacement. Researchers have built three such reactors as a pilot facility at the #Hönggerberg campus to demonstrate the technology The facility can store 10 MWh of hydrogen, which, when converted back, could yield 4-6 MWh of energy. The technology’s drawback is that it loses up to 60% of energy in the conversion steps The researchers are keen to test the technology at a larger scale and plan to store 4 GWh in reactors with a volume of 2000m3 Osama Fawzy
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💡 Researchers from ETH Zürich have been exploring using iron to store hydrogen safely and for long periods. ☀ With Switzerland set to meet more than 40% of it electricity needs with solar by 2050, the research team have been looking at using surplus solar energy to make hydrogen. 🌊 Using the solar to split water, the hydrogen is fed into a stainless-steel reactor with natural iron ore at 400°C. In here, the hydrogen extracts oxygen from the iron ore, resulting in elemental iron and water. ◀ This process can then be reversed in the winter, bringing back the hydrogen which can be converted into electricity or heat in a gas turbine or fuel cell. #hydrogen #hydrogenstorage #ironore #solar #netzero
Swiss researchers exploring using iron for hydrogen storage
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Swiss researchers at ETH Zurich have developed a promising method for hydrogen storage by reducing iron oxide to iron, enabling the hydrogen to be stored and later released through oxidation with water. - 🌞 Seasonal Storage: Hydrogen produced in summer using solar power can be stored in iron for use in winter. - ⚙️ Simple Reactor: The system uses a stainless steel tank filled with powdered iron ore to facilitate the storage and release process. - 🔥 Energy Recovery: Though not perfectly efficient, heat loss can be mitigated by repurposing it elsewhere, enhancing overall energy utilization. #HydrogenStorage #GreenEnergy #Renewables - 🌍 This method could make hydrogen grids and hydrogen-powered vehicles more feasible. - 💡 Despite energy losses, this approach provides a new avenue for long-term, seasonal energy storage. - 🚗 While not ideal for vehicles, it could be useful for grid-level energy storage solutions. https://lnkd.in/gJHhgQr8
Swiss Researchers May Have Solved Hydrogen Storage
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Global hydrogen production may grow fivefold - IEA The IEA’s latest report reveals rapid growth in low-emissions hydrogen, but policies to boost demand lag behind. Investors remain interested, while China leads global electrolyser capacity with over 40% of new projects. https://lnkd.in/eqRFcK9A International Energy Agency (IEA) IEA Fatih Birol #globalhydrogenreview #lowemissionshydrogen #electrolysercapacity #hydrogenprojects #industrialemissions MENA Newswire #policymakers #hydrogenindustry #cleantechnology
IEA report urges stronger policy support for low-emissions hydrogen demand
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The U.S. Department of Energy has set a goal to make green hydrogen domestically at $1 per kilogram by 2030. Current costs range from $3 to $8 and none of it is being done at scale. Getting the cost of green hydrogen down is a serious concern for policymakers and industry alike. Most efforts are through electrolysis, which used electricity to split the water that delivers the hydrogen production. Jennifer Chu at MIT describes research there on the solar thermochemical hydrogen process (STCH) which uses the heat from concentrated sunlight. Existing STCH designs have limited efficiency and are costly: only about 7% of incoming sunlight is utilised to make the hydrogen. The new process has a rotating train of small reactor modules where super-heated steam oxidises a metal, releasing the hydrogen. The breakthrough is the way the metal is efficiently reduced (i.e. de-oxidised), enabling the process to start again. The new system allows 40% of the sunlight to be utilised. It’s modular and scalable, though still at the design stage. The research team expect to build a prototype within the year. https://lnkd.in/eu9W4KRb
Improved “Solar Thermochemical” process captures 40% of the sun’s heat to produce Green Hydrogen - Energy Post
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“SA #hydrogeneconomy gets a boost Investing in a hydrogen fund might just be the next big thing – the industry is set to take off as soon as scientists figure out a way to reduce the production cost of #greenhydrogen .” Adriaan Kruger - 12 Jun 2024 “More research money is flowing into #hydrogen projects worldwide, with proponents of #hydrogenfuelcells and #internalcombustionengines using hydrogen as fuel, claiming these will be the power plants of the future rather than #batteries and #electricmotors .” “SA is getting in on the action and several studies are underway to look at the feasibility of building plants to produce ‘green hydrogen’ – hydrogen that is produced using #renewableenergysources .” “Really green” “Research published by Research Gate says hydrogen solves a lot of the problems associated with other forms of energy.” “”Perhaps the biggest of these is #energystorage . #Wind and #solarpower can only be generated when it’s windy or sunny, and the batteries available today are expensive and require vast amounts of #lithium and other minerals.”” https://lnkd.in/eiiHEXmH Source- original post Read all my posts #MariusPreston
SA hydrogen economy gets a boost
moneyweb.co.za
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A new report from the Transition Accelerator and the Saskatchewan Research Council (SRC) has concluded that a hydrogen hub in the Regina-Moose Jaw Industrial Corridor (RMJIC) has potential for the successful development of an industrial hydrogen supply chain and related CCUS infrastructure. The global and Canadian hydrogen markets are both expected to grow dramatically in the coming decades—the International Energy Agency estimates low-carbon hydrogen could account for 10% of global energy consumption by 2050, and the federal Hydrogen Strategy estimates the global market for hydrogen could reach $2.5 trillion in that time. Co-authored by SRC and University of Regina, “Hydrogen Hub Potential: A Feasibility Study for the Regina-Moose Jaw Industrial Corridor" looks at the potential for the RMJIC to tap into that opportunity, producing, using, and exporting hydrogen to help build Saskatchewan’s economy towards a net-zero future. #hydrogen #hydrogenenergy #hydrogenindustry #netzero #cleanenergy #cleantech #decarbonization #hydrogenduelcell #hydrogenhub https://lnkd.in/gFuvtzJP
Report Explores Regina-Moose Jaw Industrial Corridor (RMJIC)'s Potential Hydrogen Economy
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Commercial production of white hydrogen is unlikely to be achieved in the short term, and it is even less likely to significantly change the current situation of hydrogen energy and even the new energy supply, writes ANBOUND's researcher Xia Ri in an article published in the Asian Power Magazine. #whitehydrogen #hydrogen #newenergy #greenenergy #enviromental https://lnkd.in/e2QSkEry
Commercial production of white hydrogen unlikely in the short term
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This is a significant innovation in hydrogen storage technology, using iron as an inexpensive medium for storing hydrogen. This team of Swiss researchers has developed a method that allows iron to absorb and release hydrogen efficiently, which could revolutionise the way hydrogen is stored and utilised in various applications, particularly in transportation. The process involves converting iron into iron hydride, which can store hydrogen at a much lower cost compared to current methods. This advancement not only enhances the feasibility of hydrogen as an energy carrier but also addresses some of the economic barriers that have previously hindered its widespread adoption. Because hydrogen extraction and storage was less competitive compared to electric vehicles, but now, with this new approach, the economic viability of hydrogen-powered vehicles could improve dramatically, potentially leading to increased investment and development in this sector. As countries strive to meet climate goals and reduce reliance on fossil fuels, innovations like this could influence energy policies globally. Governments may begin prioritising investments in hydrogen technologies alongside renewable energy sources such as wind and solar power. The introduction of cost-effective hydrogen storage solutions could shift market dynamics within the automotive industry. Automakers might pivot towards developing more hydrogen fuel cell vehicles if they see a viable market emerging due to improved infrastructure and public acceptance driven by environmental concerns. #transportation #hydrogen #energy #ev #cars #r&d https://lnkd.in/e2ps7DE2
Iron as an inexpensive storage medium for hydrogen
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Leading the way into the #cleanenergyeconomy. We know that there is great potential for #hydrogen in #Saskatchewan. #cleanenergytransition #wind #solar https://lnkd.in/eS_k7GDu
A new report from the Transition Accelerator and the Saskatchewan Research Council (SRC) has concluded that a hydrogen hub in the Regina-Moose Jaw Industrial Corridor (RMJIC) has potential for the successful development of an industrial hydrogen supply chain and related CCUS infrastructure. The global and Canadian hydrogen markets are both expected to grow dramatically in the coming decades—the International Energy Agency estimates low-carbon hydrogen could account for 10% of global energy consumption by 2050, and the federal Hydrogen Strategy estimates the global market for hydrogen could reach $2.5 trillion in that time. Co-authored by SRC and University of Regina, “Hydrogen Hub Potential: A Feasibility Study for the Regina-Moose Jaw Industrial Corridor" looks at the potential for the RMJIC to tap into that opportunity, producing, using, and exporting hydrogen to help build Saskatchewan’s economy towards a net-zero future. #hydrogen #hydrogenenergy #hydrogenindustry #netzero #cleanenergy #cleantech #decarbonization #hydrogenduelcell #hydrogenhub https://lnkd.in/gFuvtzJP
Report Explores Regina-Moose Jaw Industrial Corridor (RMJIC)'s Potential Hydrogen Economy
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Khalifa University Researchers Explore Hydrogen Sulfide’s Role In Global Energy Transition Hydrogen is gaining prominence as a key player in addressing global energy needs, with predictions indicating a surge in demand from 90 million tons in 2020 to a potential 500 million tons or more by 2050. Despite these promising projections, current production capacities are falling short. A team of researchers from Khalifa University’s Research and Innovation Center on CO2 and Hydrogen (RICH) delved into the techno-economic feasibility and environmental impacts of large-scale hydrogen production from methane and hydrogen sulfide. Led by Prof. Lourdes Vega, the team focused on hydrogen sulfide-based thermal non-catalytic hydrogen production processes, benchmarking them against conventional and […] Read the full story here: https://lnkd.in/dpHT6yAj #solarenergy #alternativeenergy #solarpv #pvsolar #photovoltaic #cleanenergy #cleantech #climatechange #middleeast #africa #india #asiapacific #asia #energytransition #greenhydrogen #khalifauniversity’sresearchandinnovationcenter #middleeast #renewableenergy #uae
Khalifa University Researchers Explore Hydrogen Sulfide’s Role In Global Energy Transition
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