Tenaska的动态

?? Catalyzing the Transition to Green Ammonia Production Ammonia is a cornerstone of global agriculture, but the traditional production methods are energy-intensive and carbon-heavy. The shift towards green ammonia is not just an innovation—it's a necessity for a sustainable future. To know more https://lnkd.in/gAEXcEE3 #GreenAmmonia #SustainableChemistry #RenewableEnergy #Innovation #Catalysts #ChemicalIndustry #chemicaltoday

Traceability is essential for ensuring sustainability in biofuel production. Farmers Edge provides a comprehensive platform to capture on-farm data, accurately calculating grain carbon intensity (CI) and rewarding growers for regenerative farming practices. By moving beyond generic CI benchmarks, we empower farmers to achieve higher yields with low-CI grain. With user-friendly traceability software, we’re building confidence in the future of sustainable agriculture. Interested in learning more? Feel free to reach out with questions or introductions! #AgTech

A new mobile biochar kiln uses syngas recirculation for efficient biochar production from agricultural residues. Optimized for farmers, it enhances yield, energy efficiency, and economic viability while producing high-quality biochar with carbon sequestration potential, supporting sustainable agriculture and waste management practices. https://buff.ly/4h968C0 #Biochar #Pyrolysis #CarbonCapture

?? Revolutionizing Agriculture with Low-Energy Ammonia Production ?? Ammonia is the backbone of modern agriculture, crucial for producing nitrogen-based fertilizers that feed billions. However, traditional ammonia production, primarily through the Haber-Bosch process, comes at a high environmental cost, consuming immense amounts of energy and contributing to around 2% of global carbon emissions. We explore groundbreaking research from RMIT University that could transform this landscape. By utilizing innovative liquid metal catalysts like copper and gallium, scientists have found a way to produce ammonia using significantly lower energy—cutting heat by 20% and pressure by an impressive 98%. This breakthrough not only makes ammonia production more cost-effective but also opens the door to more sustainable agricultural practices, reducing reliance on fossil fuels and lowering the carbon footprint of farming. Discover how this advancement could herald a new era in agriculture, making it greener, more efficient, and more sustainable than ever before. ?? #SustainableAgriculture #GreenTech #AmmoniaProduction #ClimateChange #FutureOfFarming #Sustainability #LiquidMetals #AgriculturalTechnology https://lnkd.in/e8Yzm3Mx

?? Greener Agriculture with Low-Energy Ammonia ??. Ammonia is essential for producing fertilizers but traditionally requires energy-intensive processes. RMIT University are revolutionizing ammonia production using liquid metal catalysts. This new method drastically reduces energy needs and cuts emissions, paving the way for more sustainable farming practices. Discover how this breakthrough could reshape the future of agriculture! ??#AmmoniaProduction #ClimateChange #FutureOfFarming #Sustainability #LiquidMetals?

Nitin Gadkari discusses his initiatives to support Indian farmers through sustainable technology. He highlights the introduction of CNG-powered tractors, which save farmers up to ?1,00,000 annually, and the adoption of solar pumps that eliminate electricity costs. Gadkari emphasizes the importance of reducing agricultural expenses and achieving balance among stakeholders through these innovations. This clip sheds light on how renewable and cost-effective solutions can empower India’s agricultural sector. Watch the full interview with Dr Prannoy Roy, Dorab R. Sopariwala and Sohit Mishra here: https://lnkd.in/gEajPuhp

?? Exciting Developments in #Hydrogen Agriculture ?? As the pursuit of #sustainable farming practices continues, hydrogen #agriculture emerges as a promising solution with the potential to revolutionize the agricultural sector. ???? Hydrogen agriculture utilizes hydrogen gas and fuel cell technology to power various farming processes, offering a cleaner and more environmentally friendly alternative to conventional methods. Here's how: 1?? Zero-Emission Machinery: Hydrogen fuel cell-powered tractors, developed by industry leaders, provide an eco-friendly alternative to diesel-powered equipment, reducing greenhouse gas emissions in the field. 2?? Cleaner Fertilizers: Green hydrogen fertilizers, produced through electrolysis using renewable energy sources, offer the same crop nutrition as traditional fertilizers but without the environmental impact. 3?? Efficient Post-Harvest Processes: Hydrogen generators provide a reliable source of heat for activities like grain drying and cooling, reducing reliance on fossil fuels and minimizing emissions. The potential of hydrogen agriculture doesn't stop here. As technology continues to advance, we can anticipate further innovations, including hydrogen-powered harvesters, irrigation systems, greenhouses, and autonomous machinery, paving the way for a greener and more sustainable future in farming. ???? #HydrogenAgriculture #SustainableFarming #CleanEnergy #Innovation #EnvironmentalSustainability

Exploring the Interconnectedness of Our Ecosystem: From Agriculture to Biofuel ? Have you ever considered how different aspects of our ecosystem are interlinked? Let's take a journey from agriculture to biofuel and see how unknown connections impact us: Agriculture ? Corn? Corn Starch? Glucose? Ethanol? Biofuel ? Each step in this process showcases the incredible interconnectedness of our ecosystem. Understanding these links helps us appreciate the complexity and importance of sustainable practices in agriculture and energy production. For more such content, follow Quest2Analyze! https://quest2analyze.com/ #sustainability #biofuel #agriculture #ecosystem #renewableenergy #circulareconomy #innovation #greenenergy #environmentalimpact #quest2analyze

?? Are Sodium-Ion Batteries the Key to the Future of Sustainable Agriculture? ?? As global energy demands continue to grow, particularly in key sectors like agriculture, we face the challenge of finding more sustainable and cost-effective energy solutions. Agriculture, being one of the most critical industries worldwide, has seen a sharp increase in energy needs with advances in technology and levels of automation. Against this backdrop, sodium-ion batteries have emerged as a promising new energy technology with great potential. ?? Energy Challenges in Modern Agriculture Agriculture not only requires energy to support traditional farming activities but also needs to power a variety of automated equipment, including everything from irrigation systems to smart monitoring devices. These technologies rely on stable and reliable energy sources, especially in remote areas or off-grid farms. ?? Introduction to Sodium-Ion Battery Technology Sodium-ion batteries work by moving sodium ions between the battery's cathode and anode to store and release energy. This is very similar to the well-known lithium-ion batteries, but sodium is cheaper and more abundant. Sodium is widely distributed and easy to extract from the earth, offering a more economical and sustainable option. Sodium-ion batteries show good cycle stability during charging and discharging, although their energy density is slightly lower than the best lithium-ion batteries. ?? Environmental and Economic Advantages Sodium-ion batteries offer significant advantages in terms of environmental friendliness and cost-effectiveness. They use materials that are cheaper and easier to obtain, and they have a smaller environmental impact during production. This makes sodium-ion batteries an ideal choice for agriculture, especially in cost-sensitive and growing markets. By adopting sodium-ion batteries, agricultural producers can reduce dependence on fossil fuels, lower operational costs, and contribute to sustainable development in agricultural production. ?? Conclusion With ongoing technological advancements and further cost reductions, sodium-ion batteries are poised to play an increasingly significant role in global agriculture. They not only help the agricultural sector meet growing energy demands but also drive the industry towards a greener, more efficient future. I am very excited to see how this technology continues to evolve and make an impact in practical applications. If you have more ideas or insights about the application of sodium-ion batteries in agriculture or other fields, feel free to share them in the comments! #SustainableAgriculture #RenewableEnergy #BatteryTechnology #Innovation #AgriculturalTech #SodiumIon

?? Are Sodium-Ion Batteries the Key to the Future of Sustainable Agriculture? ?? As global energy demands continue to grow, particularly in key sectors like agriculture, we face the challenge of finding more sustainable and cost-effective energy solutions. Agriculture, being one of the most critical industries worldwide, has seen a sharp increase in energy needs with advances in technology and levels of automation. Against this backdrop, sodium-ion batteries have emerged as a promising new energy technology with great potential. ?? Energy Challenges in Modern Agriculture Agriculture not only requires energy to support traditional farming activities but also needs to power a variety of automated equipment, including everything from irrigation systems to smart monitoring devices. These technologies rely on stable and reliable energy sources, especially in remote areas or off-grid farms. ?? Introduction to Sodium-Ion Battery Technology Sodium-ion batteries work by moving sodium ions between the battery's cathode and anode to store and release energy. This is very similar to the well-known lithium-ion batteries, but sodium is cheaper and more abundant. Sodium is widely distributed and easy to extract from the earth, offering a more economical and sustainable option. Sodium-ion batteries show good cycle stability during charging and discharging, although their energy density is slightly lower than the best lithium-ion batteries. ?? Environmental and Economic Advantages Sodium-ion batteries offer significant advantages in terms of environmental friendliness and cost-effectiveness. They use materials that are cheaper and easier to obtain, and they have a smaller environmental impact during production. This makes sodium-ion batteries an ideal choice for agriculture, especially in cost-sensitive and growing markets. By adopting sodium-ion batteries, agricultural producers can reduce dependence on fossil fuels, lower operational costs, and contribute to sustainable development in agricultural production. ?? Conclusion With ongoing technological advancements and further cost reductions, sodium-ion batteries are poised to play an increasingly significant role in global agriculture. They not only help the agricultural sector meet growing energy demands but also drive the industry towards a greener, more efficient future. I am very excited to see how this technology continues to evolve and make an impact in practical applications. If you have more ideas or insights about the application of sodium-ion batteries in agriculture or other fields, feel free to share them in the comments! #SustainableAgriculture #RenewableEnergy #BatteryTechnology #Innovation #AgriculturalTech #SodiumIon