ADVANCED HYDROGEN TRANSPORT MEMBRANES FOR VISION 21 FOSSIL FUEL PLANTS | Zendy

Shane E. Roark | Zendy; Anthony F. Sammells | Zendy; Richard Mackay | Zendy; Lyrik Y. Pitzman | Zendy; Thomas A. Zirbel | Zendy; Thomas F. Barton | Zendy; Sara L Rolfe | Zendy; U. Balachandran | Zendy; Richard N. Kleiner | Zendy; James E. Stephan | Zendy; Frank E. Anderson | Zendy; G.A. Farthing | Zendy; D.R. Rowley | Zendy; Tim R Armstrong | Zendy; Robert D. Carneim | Zendy; P F Becher | Zendy; C.H. Hsueh | Zendy; Aaron L. Wagner | Zendy; Jon P. Wagner | Zendy

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ADVANCED HYDROGEN TRANSPORT MEMBRANES FOR VISION 21 FOSSIL FUEL PLANTS

Author(s) -

Shane E. Roark,

Anthony F. Sammells,

Richard Mackay,

Lyrik Y. Pitzman,

Thomas A. Zirbel,

Thomas F. Barton,

Sara L Rolfe,

U. Balachandran,

Richard N. Kleiner,

James E. Stephan,

Frank E. Anderson,

G.A. Farthing,

D.R. Rowley,

Tim R Armstrong,

Robert D. Carneim,

P F Becher,

C.H. Hsueh,

Aaron L. Wagner,

Jon P. Wagner

Publication year - 2002

Publication title -

osti oai (u.s. department of energy office of scientific and technical information)

Language(s) - English

Resource type - Reports

DOI - 10.2172/794325

Subject(s) - oak ridge national laboratory , fossil fuel , national laboratory , hydrogen , membrane , coal , ceramic , waste management , microstructure , environmental science , engineering , materials science , process engineering , chemical engineering , chemistry , engineering physics , composite material , organic chemistry , physics , biochemistry , nuclear physics

Eltron Research Inc., and team members CoorsTek, McDermott Technology, inc., Sued Chemie, Argonne National Laboratory, and Oak Ridge National Laboratory are developing an environmentally benign, inexpensive, and efficient method for separating hydrogen from gas mixtures produced during industrial processes, such as coal gasification. This project was motivated by the National Energy Technology Laboratory (NETL) Vision 21 initiative which seeks to economically eliminate environmental concerns associated with the use of fossil fuels. This objective is being pursued using dense membranes based in part on Eltron-patented ceramic materials with a demonstrated ability for proton and electron conduction. The technical goals are being addressed by modifying single-phase and composite membrane composition and microstructure to maximize proton and electron conductivity without loss of material stability. Ultimately, these materials must enable hydrogen separation at practical rates under ambient and high-pressure conditions, without deactivation in the presence of feedstream components such as carbon dioxide, water, and sulfur

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