How Landfill Gas to Renewable Natural Gas helped by eRIN?

Landfill gas (LFG) to RNG (Renewable Natural Gas) projects can benefit from the eRIN system by allowing them to generate and sell renewable energy credits based on the amount of renewable energy produced from the landfill gas. These credits can be bought and sold on the open market, providing a financial incentive for the production of renewable energy and helping to support the growth of the renewable energy industry.

what is eRIN?

eRIN stands for Electronic Renewable Identification Number. It is a system used in the renewable energy sector to track the production and use of renewable energy. An eRIN is a unique identifier assigned to each unit of renewable energy that is produced and can be used to demonstrate that a unit of energy was generated from a renewable source. The eRIN system helps to ensure the authenticity and accountability of renewable energy transactions and provides a means of tracking and verifying renewable energy production and use.

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Green Urea: A Sustainable and Eco-Friendly Fertilizer for Agriculture

Fertilizers are an essential component of modern agriculture, providing the nutrients necessary for plants to grow and produce high yields. However, the production of traditional fertilizers is often associated with significant environmental impacts, including greenhouse gas emissions and pollution of waterways and soil. Green urea is a new type of fertilizer that offers a more sustainable and eco-friendly alternative to traditional urea. What is Green Urea? Green urea is a type of fertilizer that is produced using renewable energy sources and sustainable production methods. Unlike traditional urea, which is primarily made from non-renewable fossil fuels, green urea is made using carbon dioxide captured from industrial emissions or directly from the atmosphere, and hydrogen generated from renewable energy sources such as solar, wind, or hydropower. The production process of green urea involves the electrochemical reduction of carbon dioxide to form carbon monoxide and hydrogen, followe...

Difference between the AEM and PEM electrolyzers

AEM (Anion Exchange Membrane) and PEM (Proton Exchange Membrane) electrolyzers are both types of electrolysis devices that use electricity to split water into its constituent parts, hydrogen and oxygen. However, there are some key differences between these two types of electrolyzers. Technical Difference The main technical difference between AEM (Anion Exchange Membrane) and PEM (Proton Exchange Membrane) electrolyzers lies in the type of membrane used and the resulting electrochemical reactions that occur. Membrane Material: AEM electrolyzers use an anion exchange membrane that selectively allows negatively charged ions (such as hydroxide ions) to pass through, while blocking positively charged ions (such as hydrogen ions). In contrast, PEM electrolyzers use a proton exchange membrane that selectively allows only positively charged ions (protons) to pass through. Electrolyte: AEM electrolyzers use an alkaline electrolyte (such as potassium hydroxide), while PEM electrolyzers use an a...

Haber-Bosch Process: List of Catalysts

The Haber-Bosch process is an important industrial process for the production of ammonia, which is used as a fertilizer and a key raw material for the production of various chemicals. The process involves the reaction of nitrogen gas and hydrogen gas in the presence of a catalyst to produce ammonia. Over the years, several catalysts have been developed for the Haber-Bosch process . In this article, we will discuss some of the most widely used catalysts for this process. Iron-Based Catalysts: Iron-based catalysts were the first catalysts used in the Haber-Bosch process and remain the most widely used today. These catalysts are typically composed of iron oxide (Fe 2 O 3 ) or iron carbide (Fe 3 C) supported on a high surface area material such as alumina. These catalysts typically operates at temperatures between 400°C and 550°C and pressures ranging from 150-300 bar. The feed gas, which consists of nitrogen and hydrogen, is introduced to the catalyst bed at a ratio of 1:3. Iron-bas...

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