Chemistry: fischer-tropsch processes; or purification or recover – Group ib metal containing catalyst utilized for the...
Reexamination Certificate
2008-07-22
2008-07-22
Silverman, Stanley S. (Department: 1793)
Chemistry: fischer-tropsch processes; or purification or recover
Group ib metal containing catalyst utilized for the...
C423S625000, C423S628000, C502S302000, C502S303000, C502S304000, C502S305000, C502S306000, C502S307000, C502S308000, C502S309000, C502S310000, C502S311000, C502S312000, C502S317000, C502S318000, C502S319000, C502S320000, C502S321000, C502S322000, C502S324000, C502S326000, C502S328000, C502S330000, C502S331000, C502S332000, C502S333000, C502S334000, C502S335000, C502S337000, C502S339000, C502S340000, C502S341000, C502S342000, C502S343000, C502S344000, C502S345000, C502S346000, C502S347000, C502S348000, C502S
Reexamination Certificate
active
10687140
ABSTRACT:
This invention relates to methods for making a stabilized transition alumina of enhanced hydrothermal stability, which include the introduction of at least one structural stabilizer; a steaming step before or after the introduction step, wherein steaming is effective in transforming a transition alumina at least partially to boehmite and/or pseudoboehmite; and a calcining step to create a stabilized transition alumina. The combination of the structural stabilizer and the steaming step is believed to impart high hydrothermal stability to the alumina crystal lattice. Particularly preferred structural stabilizers include boron, cobalt, and zirconium. The stabilized transition alumina is useful as a catalyst support for high water partial pressure environments, and is particularly useful for making a catalyst having improved hydrothermal stability. The invention more specifically discloses Fischer-Tropsch catalysts and processes for the production of hydrocarbons from synthesis gas.
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Espinoza Rafael L.
Ionkina Olga P.
Jin Yaming
Srinivasan Nithya
Conley & Rose, P.C.
ConocoPhillips Company
Fiorito James
Silverman Stanley S.
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