James P. Szybist
Pennsylvania State University
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Featured researches published by James P. Szybist.
Archive | 2006
Robert Abbott; Edward S. Casey; Etop Esen; Douglas Smith; Bruce Burke; Binh Nguyen; Samuel Tam; Paul Worhach; Mahabubul Alam; Juhun Song; James P. Szybist; Ragini Acharya; Vince Zello; David C. Morris; Patrick J. Flynn; Stephen R. Kirby; Krishan Bhatia; Jeff Gonder; Yun Wang; Wenpeng Liu; Hua Meng; Subramani Velu; Weidong Gu Jian-Ping Shen; Elise S. Bickford; Chunshan Song; Chao-Yang Wang; Andre' Boehman
ConocoPhillips, in conjunction with Nexant Inc., Penn State University, and Cummins Engine Co., joined with the U.S. Department of Energy (DOE) National Energy Technology Laboratory (NETL) in a cooperative agreement to perform a comprehensive study of new ultra clean fuels (UCFs) produced from remote sources of natural gas. The project study consists of three primary tasks: an environmental Life Cycle Assessment (LCA), a Market Study, and a series of Engine Tests to evaluate the potential markets for Ultra Clean Fuels. The overall objective of DOEs Ultra Clean Transportation Fuels Initiative is to develop and deploy technologies that will produce ultra-clean burning transportation fuels for the 21st century from both petroleum and non-petroleum resources. These fuels will: (1) Enable vehicles to comply with future emission requirements; (2) Be compatible with the existing liquid fuels infrastructure; (3) Enable vehicle efficiencies to be significantly increased, with concomitantly reduced CO{sub 2} emissions; (4) Be obtainable from a fossil resource, alone or in combination with other hydrocarbon materials such as refinery wastes, municipal wastes, biomass, and coal; and (5) Be competitive with current petroleum fuels. The objectives of the ConocoPhillips Ultra Clean Fuels Project are to perform a comprehensive life cycle analysis and to conductmorexa0» a market study on ultra clean fuels of commercial interest produced from natural gas, and, in addition, perform engine tests for Fisher-Tropsch diesel and methanol in neat, blended or special formulations to obtain data on emissions. This resulting data will be used to optimize fuel compositions and engine operation in order to minimize the release of atmospheric pollutants resulting from the fuel combustion. Development and testing of both direct and indirect methanol fuel cells was to be conducted and the optimum properties of a suitable fuel-grade methanol was to be defined. The results of the study are also applicable to coal-derived FT liquid fuels. After different gas clean up processes steps, the coal-derived syngas will produce FT liquid fuels that have similar properties to natural gas derived FT liquids.«xa0less
Fuel Processing Technology | 2007
James P. Szybist; Juhun Song; Mahabubul Alam; André L. Boehman
Energy & Fuels | 2004
André L. Boehman; David C. Morris; James P. Szybist; Etop Esen
Fuel Processing Technology | 2005
James P. Szybist; André L. Boehman; Joshua D. Taylor; Robert L. McCormick
Energy & Fuels | 2005
James P. Szybist; Stephen R. Kirby; André L. Boehman
Combustion and Flame | 2007
James P. Szybist; André L. Boehman; Daniel C. Haworth; Hibiki Koga
SAE 2003 World Congress & Exhibition | 2003
James P. Szybist; André L. Boehman
SAE Powertrain & Fluid Systems Conference & Exhibition | 2003
James P. Szybist; John Simmons; Matthew L. Druckenmiller; Khalid Al-Qurashi; André L. Boehman; Alan W. Scaroni
Energy & Fuels | 2014
Derek A. Splitter; James P. Szybist
Energy & Fuels | 2014
Derek A. Splitter; James P. Szybist
