Researchers Develop an Organic Liquid Capable of Pulling CO2 and Sulfur from Industrial Emissions

admin — Mon, 31 Aug 2009 13:24:25 +0000

The Department of Energy’s Pacific Northwest National Laboratory has developed a reusable organic liquid that can pull harmful gases such as carbon dioxide or sulfur dioxide out of industrial emissions from power plants. The process could directly replace current methods and allow power plants to capture double the amount of harmful gases in a way that uses no water, less energy and saves money.

“Power plants could easily retrofit to use our process as a direct replacement for existing technology,” said David Heldebrant, PNNL’s lead research scientist for the project.

Harmful gases such as carbon dioxide or sulfur dioxide are called “acid gases.” The new scrubbing process uses acid gas-binding organic liquids that contain no water and appear similar to oily compounds. These liquids capture the acid gases near room temperature. Scientists then heat the liquid to recover and dispose of the acid gases properly.

These recyclable liquids require much less energy to heat but can hold two times more harmful gases by weight than the current leading liquid absorbent used in power plants. It is a combination of water and monoethanolamine, a basic organic molecule that grabs the carbon dioxide.

Click here to watch a video of the process.

PNNL’s previous work with the all-organic liquids focused on pulling only carbon dioxide out of emissions from power plants. New work will show how the process can be applied to other acid gases such as sulfur dioxide.

“Current methods used to capture and release carbon dioxide emissions from power plants use a lot of energy because they pump and heat an excess of water during the process,” said Heldebrant. He notes the monoethanolamine component is too corrosive to be used without the excess water.

In PNNL’s process called “Reversible Acid Gas Capture,” the molecules that grab onto the acid gases are already in liquid form, and don’t contain water. The acid gas-binding organic liquids require less heat than water does to release the captured gases.

Heldebrant and colleagues demonstrated the process in previous work with a carbon dioxide-binding organic liquid, called CO2BOL. In this process, scientists mix the CO2BOL solution into a holding tank with emissions that contain carbon dioxide. The CO2BOL chemically binds with the carbon dioxide to form a liquid salt solution.

In another tank, scientists reheat the salt solution to strip out the carbon dioxide. Non-hazardous gases such as nitrogen would not be captured and are released back into the atmosphere. The toxic compounds are captured separately for storage. At that point, the CO2BOL solution is back in its original state and ready for reuse.

Heldebrant and colleagues have developed organic liquid systems that bind three additional acid gases found in emissions. He will talk about new work with sulfur dioxide, carbonyl sulfide and carbon disulfide — all acid gases that are environmentally harmful — at the American Chemical Society Fall 2009 Meeting and Exposition, Tuesday, August 18, at 4:30 p.m. EDT.

LED and Organic LED Research Gets $6.4 Million Boost in Funding

admin — Mon, 24 Aug 2009 20:14:46 +0000

U.S. Department of Energy (DOE) Secretary Steven Chu today announced the investment of up to $6.4 million, including $4.6 million from the American Recovery and Reinvestment Act, for four projects designed to advance research and development of next generation high-efficiency lighting.

The selections announced today are part of DOE’s continuing work to accelerate progress toward creating a United States-led market for high-efficiency solid-state lighting sources that save more energy, reduce costs, and have less environmental impact than conventional light sources.

The selections are being made in response to the Department’s solicitation to national laboratories for Solid-State Lighting (SSL) Core Technology Research. With a potential tenfold improvement over standard incandescent lamps, these selections focus on improving the efficiency and quality of solid-state white light sources. By leveraging the scientific resources of the DOE national laboratories, several technology barriers will be addressed to advance SSL toward its full potential. These selections are expected to fill key technology gaps in both light emitting diode (LED) and organic light emitting diode (OLED) technologies. These awards also represent a significant advancement in the SSL technology base, with results that can be applied to existing and future lighting products that are energy efficient and cost-effective.

National Renewable Energy Laboratory, Golden, Colorado: NREL will seek to demonstrate the viability of high bandgap gallium indium phosphide alloys for synthesis of inexpensive, efficient green LED devices. NREL will receive $1.8 million in funding from the American Recovery and Reinvestment Act.

Pacific Northwest National Laboratory, Richland, Washington: PNNL seeks to develop new, stable materials for high-efficiency blue OLEDs. PNNL will receive $1.0 million in funding from the American Recovery and Reinvestment Act.

Sandia National Laboratories, Albuquerque, New Mexico: SNL seeks to improve the efficiency of green LEDs by growing on gallium nitride substrates. Sandia will receive $1.8 million in funding from the American Recovery and Reinvestment Act.

U.S. ARMY Research Laboratory, Adelphi, Maryland: ARL seeks to exploit the negative polarization charge at the active region to achieve efficient green LEDs. ARL will receive $1.8 million from appropriated program funds.

ENERGY-THINK! » Pacific Northwest Labs

Researchers Develop an Organic Liquid Capable of Pulling CO2 and Sulfur from Industrial Emissions

LED and Organic LED Research Gets $6.4 Million Boost in Funding