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Biodiesel A New Way of Turning Plants into Fuel
Biodiesel An Alternative Fuel Available Now
Biodiesel An Industry Poised for Growth
Biodiesel Facts For Kids
Biodiesel For Diesel Fuel Use
Biodiesel Keeps Home Fire Burning
Biodiesel Plan Spans Border
Biodiesel Refinery In Romania
Biofuel Cells To Replace Rechargeable Batteries
Biofuels As A Source Of Energy
Biofuels Fill Your Tank With Natures Goodness
Biofuels For Transport
Biological Ways Of Producing Ethanol
Cool Fuel Cells
Ethanol
Ethanol Based Biodiesel
Fill Er Up Full Of Beans
From Fuel To Pure Water
Fuel Alcohol From Pea Starch
Fuel Cell Benefits
Fuel Cell Cars
Fuel Cell Challenges
Fuel Cell Efficiency
Fuel Cell History
Fuel Cell Vehicle Benefits
Fuel Cell Vehicles General Information
Grass Hailed As Potential Source Of Clean Energy
How They Work Hydrogen Sources
Hybrid Electric And Fuel Cell Vehicles
Hydrogen Challenges
Hydrogen Delivery
Hydrogen Overview
Investigating The Greenness Of Biobased Products
Is There A Green Car in Your Future
Making Biodiesel Fuel at Home
RP To Mass Produce Sugar Sorghum For Bio Fuel
Running On Vegetables
Some Alcohol Fuels Facts
The Alcohols Ethanol And Methanol
Veggie Fuels Feed Bottom Line
What Is A Fuel Cell

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Hydrogen Overview

Hydrogen Overview

Hydrogen is the lightest and most abundant element in the universe. It is an energy carrier, not an energy source, meaning that it stores and delivers energy in a usable form. In its pure form (H2), it is a colorless and odorless gas. However, since it combines easily with other elements, hydrogen is rarely found by itself in nature and is usually found as a part of other compounds, including fossil fuels, plant material, and water. Hydrogen Production

Hydrogen can be produced using a variety of domestic energy resources - fossil fuels, such as coal and natural gas, with carbon capture and sequestration; renewables, such as biomass, and renewable energy technologies, including solar, wind, geothermal, and hydropower; and nuclear power. Specific technologies and processes are described below. Thermochemical Processes

* Steam methane reforming: In this process, high-temperature steam is used to extract hydrogen from a methane source such as natural gas. This is the most common method of producing hydrogen; about 95 percent of the hydrogen we use today in the United States is produced using this process.

* Partial oxidation: Scientists are exploring a process that produces hydrogen by simultaneously separating oxygen from air and partially oxidizing methane.

* Other thermal processes: Other processes include (1) splitting water using heat from a solar concentrator, and (2) gasifying or burning biomass (i.e., biological material, such as plants or agricultural waste) to generate a bio-oil or gas, which is then reformed to produce hydrogen.

Electrolytic Processes

* Electrolysis: In electrolysis, electricity is used to separate water (H2O) into hydrogen and oxygen. Current electrolysis systems are very energy intensive. The challenge is to develop low cost and more energy efficient electrolysis technologies.

Photolytic Processes

* Photolytic methods: In photolysis, sunlight is used to split water. Two photolytic processes are being explored: (1) photobiological methods, in which microbes, when exposed to sunlight, split water to produce hydrogen, and (2) photoelectrolysis, in which semi-conductors, when exposed to sunlight and submersed in water, generate enough electricity to produce hydrogen by splitting the water.