Ethylene, the world's most commonly produced organic compound, is used many types of industries. Farmers and horticulturalists use it as a plant hormone to promote flowering and ripening, especially in bananas while doctors and surgeons have long used ethylene as an anesthetic and ethylene-based polymers are found in everything from freezer bags to fiberglass.
Its current production methods result in a number of greenhouse gases. A new environmentally friendly technology created by scientists at Argonne National Laboratory may revolutionize creation of this compound by use of a high-temperature membrane that can produce ethylene from an ethane stream by removing pure hydrogen. Says senior ceramist Balu Balachandran, “This is a clean, energy-efficient way of producing a chemical that before required methods that were expensive and wasteful and also emitted a great deal of pollution.”
Because the new membrane lets only hydrogen pass through it, the ethane stream does not come into contact with atmospheric oxygen and nitrogen, preventing the creation of a miasma of greenhouse gases – nitrogen oxide, carbon dioxide and carbon monoxide – associated with the traditional production of ethylene by pyrolysis, in which ethane is exposed to jets of hot steam. The world’s ethylene producers manufacture more than 75 million metric tons of ethylene per year, causing millions of metric tons’ worth of greenhouse gas emissions.
Unlike pyrolysis, which requires the constant input of heat, the hydrogen transport membrane (HTM) produces the fuel needed in order to drive the reaction. By using air on one side of the membrane, the already-transported hydrogen can react with oxygen to provide energy. “By using this membrane, we essentially enable the reaction to feed itself,” Balachandran said. “The heat is produced where it is needed.”
The new membrane reactor also performs an additional chemical trick: by constantly removing hydrogen from the stream, the membrane alters the ratio of reactants to products, enabling the reaction to make more ethylene that it theoretically could have before reaching equilibrium. “We are essentially confusing or cheating the thermodynamic limit,” Balachandran said. “The membrane reactor thinks: ‘hey, I haven’t reached equilibrium yet, let me take this reaction forward.’”
While Balachandran’s team, which included chemists Stephen Dorris, Tae Lee, Chris Marshall and Charles Scouton, designed this experiment merely to prove the membrane’s capability to produce ethylene, he hopes to extend the project by pairing with an industrial partner who would produce the membranes commercially. Since the membrane reduces the number of steps required to produce ethylene, the technology could enable the chemical to be produced more cheaply, he said.
The results of the research are expected to be presented at the 2008 Clean Technology conference in Boston in June. The work was funded by the Department of Energy's Industrial Technology Program, which resides within its Office of Energy Efficiency & Renewable Energy.
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