Harnessing the Power of Plasma for Hydrogen Storage
Plasma is like a gas, but many of its atoms have been stripped of an electron or two. These positively charged atoms swim about in a crackling-hot sea of negatively charged loose electrons, making plasmas great electrical conductors.
Kong, technical lead for plasma processing at INL, has built a career of putting plasma to work. He's using it to mass-produce nanoparticles, a project that in August received $1 million in federal stimulus funding. He's also employing plasma to find ways to store hydrogen efficiently, and he'll soon start a project using plasma to convert natural gas, coal and heavy oil to gasoline and diesel.
Kong is also working with a large multinational chemical company to find better ways to store hydrogen.
Simply putting hydrogen in a tank to power a car or appliance is difficult, because the element is a gas at all but extremely low temperatures (its boiling point is -253 degrees Celsius). Tanks holding enough low-density hydrogen gas to power anything would have to be very large, in many cases prohibitively so. Hydrogen could be liquefied — either by compression or cooling — to bring tank size down, but this would require a great deal of energy and raise safety concerns, as elemental hydrogen is very reactive. Chemical storage — in which hydrogen is locked into more complex molecules, then released later after exposure to heat and/or catalysts — strikes many scientists as more practical. But current technologies for making such chemical hydrides are complicated and energy-intensive. Kong is using plasma in an attempt to revolutionize the production process.
The current method of making these complex chemical hydrides is a 13-step process.What they are working on is potentially a one- to two-step process.Eliminating so many steps involves tricky, difficult and unstable reactions, and Kong and his team are still working out the details.
To know about the technology click here
Kong, technical lead for plasma processing at INL, has built a career of putting plasma to work. He's using it to mass-produce nanoparticles, a project that in August received $1 million in federal stimulus funding. He's also employing plasma to find ways to store hydrogen efficiently, and he'll soon start a project using plasma to convert natural gas, coal and heavy oil to gasoline and diesel.
Kong is also working with a large multinational chemical company to find better ways to store hydrogen.
Simply putting hydrogen in a tank to power a car or appliance is difficult, because the element is a gas at all but extremely low temperatures (its boiling point is -253 degrees Celsius). Tanks holding enough low-density hydrogen gas to power anything would have to be very large, in many cases prohibitively so. Hydrogen could be liquefied — either by compression or cooling — to bring tank size down, but this would require a great deal of energy and raise safety concerns, as elemental hydrogen is very reactive. Chemical storage — in which hydrogen is locked into more complex molecules, then released later after exposure to heat and/or catalysts — strikes many scientists as more practical. But current technologies for making such chemical hydrides are complicated and energy-intensive. Kong is using plasma in an attempt to revolutionize the production process.
The current method of making these complex chemical hydrides is a 13-step process.What they are working on is potentially a one- to two-step process.Eliminating so many steps involves tricky, difficult and unstable reactions, and Kong and his team are still working out the details.
To know about the technology click here
Labels: efficiency, energy, hydrogen, technology
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