Raymond Gorte Explained

Raymond J. Gorte
Honorific Prefix:Russell Pearce and Elizabeth Crimian Heuer Professor
Birth Date:1954 6, mf=yes
Birth Place:Manitowoc, Wisconsin
Nationality:American
Field:Chemical Engineer
Work Institution:University of Pennsylvania
Alma Mater:University of Minnesota
University of Wisconsin
Doctoral Advisor:Lanny D. Schmidt
Known For:Catalysis, Characterization, Fuel Cells
Prizes:Paul H. Emmett Award (1999), AIChE Wilhelm Award (2009), National Academy of Engineering (2018)

Raymond John Gorte is an American chemical engineer, currently the Russel Pearce and Elizabeth Crimian Heuer Endowed Professor of Chemical and Biomolecular Engineering (CBE) and Materials Science & Engineering (MSE) at the University of Pennsylvania. Throughout his career at the University of Pennsylvania and the University of Minnesota, he has advanced the study of fuel cells and catalysts including heterogeneous metals and zeolite materials. He is a member of the U.S. National Academy of Engineering.[1]

Early life and education

Gorte was born in Wisconsin and grew up in Manitowoc, Wisconsin. In 1976, he earned a Bachelor of Science in chemical engineering from the University of Wisconsin-Madison. He completed his Ph.D. in chemical engineering at the University of Minnesota in 1981 with advisor Lanny D. Schmidt on the topic of platinum catalysis of nitric oxide decomposition. His thesis was published in 1981 with the title, "The Kinetic Interaction of Nitric-Oxide with Single Crystal Platinum".[2]

Professor of chemical engineering

Gorte joined the University of Pennsylvania's Department of Chemical and Biomolecular Engineering in Philadelphia in 1981. He was promoted to associate professor in 1987, and professor in 1993. He is a member of the Penn Center for Energy Innovation, the Laboratory for Research on the Structure of Matter (LRSM), and the Catalysis Center for Energy Innovation.[3]

Fuel cells

Gorte's research in solid oxide fuel cells addresses the design of electrodes and applications in hydrocarbon oxidation. In 2000 he published an article in Nature with John Vohs describing the oxidation of methane and higher hydrocarbons with a composite anode of copper and ceria that achieves viable power densities while producing carbon dioxide and water.[4]

Solid acids

The design, synthesis, and utilization of solid acids such as amorphous silica-alumina, ZSM-5, or synthetic faujasite relies on an understanding of the chemical site of acidity. Gorte has proposed a description of solid acidity based on a thermochemical cycle including the proton affinity, the interaction energy, and the enthalpy of adsorption. Gorte has also developed a method for quantifying acid site concentration based on alkylamine decomposition by the Hoffmann elimination reaction occurring by temperature programmed desorption (TPD). He has recently extended this to a highly precise method of "reactive gas chromatography".[5]

Catalytic chemistry

Gorte's research in catalyst design has led to research projects on numerous applications and chemistries. He has published papers on the water-gas-shift reaction catalyzed by supported metals such as ceria-supported Pt, Pd and Rh.[6] Other applications include:

Works

Gorte has authored more than 400 journal articles on catalysis, surface chemistry, and fuels cells which includes:

With his Advisor

At Univ. of Pennsylvania

Honors

Gorte has received awards for his contributions to research, education and service, many of which highlight his interest in fuel cells and catalysis and the problems associated with characterization and fundamental mechanisms and kinetics. In 2018, Gorte was elected a member of the National Academy of Engineering. His election citation stated:

Other awards and honors include:[22]

External links

Notes and References

  1. Web site: Raymond Gorte Elected to National Academy of Engineering . tufts.edu . April 7, 2017.
  2. The Kinetic Interaction of Nitric-Oxide with Single Crystal Platinum. Gorte. Raymond John. 1981. University of Minnesota. Ph.D. .
  3. Web site: Membership - Catalysis Center for Energy Innovation. 2 March 2018.
  4. Direct oxidation of hydrocarbons in a solid-oxide fuel cell. Nature. 404. 6775. 265–267. 10.1038/35005040. 10749204. 2000. Park. Seungdoo. Vohs. John M.. Gorte. Raymond J.. 2000Natur.404..265P. 4426984 .
  5. Simple Quantification of Zeolite Acid Site Density by Reactive Gas Chromatography. Catalysis Science & Technology. 7. 17. 3831–3841. 10.1039/C7CY01068K. 2017. Abdelrahman. Omar A.. Vinter. Katherine P.. Ren. Limin. Xu. Dandan. Gorte. Raymond J.. Tsapatsis. Michael. Dauenhauer. Paul J..
  6. Studies of the water-gas-shift reaction on ceria-supported Pt, Pd, and Rh: implications for oxygen-storage properties. Applied Catalysis B: Environmental. 15. 1–2. 107–114. 10.1016/S0926-3373(97)00040-4. 1998. Bunluesin. T.. Gorte. R.J.. Graham. G.W.. free.
  7. Evidence for a second CO oxidation mechanism on Rh/ceria. Journal of Catalysis. 143. 86–91. 10.1006/jcat.1993.1255. 1993. Zafiris. G.S.. Gorte. R.J..
  8. Steam reforming of n-butane on Pd/ceria. Catalysis Letters. 73. 15–19. 10.1023/A:1009070118377. 2001. Wang. X.. Gorte. R.J.. 92757001 .
  9. Mechanistic study of alcohol dehydration on γ-Al2O3. ACS Catalysis. 2. 9. 1846–1853. 10.1021/cs300176d. 2012. Roy. Sounak. Mpourmpakis. Giannis. Hong. Do-Young. Vlachos. Dionisios G.. Bhan. A.. Gorte. R. J..
  10. Desorption Kinetics with Precursor Intermediates. Surface Science. 76. 2. 559–573. 10.1016/0039-6028(78)90114-0. 1978. Gorte. R.. Schmidt. L.D.. 1978SurSc..76..559G.
  11. Temperature Programmed Desorption with Reaction. Applications of Surface Science. 3. 3. 381–389. 10.1016/0378-5963(79)90007-2. 1979. Gorte. R.. Schmidt. L.D.. 1979ApSS....3..381G.
  12. Interactions Between NO and CO on Pt(111). Surface Science. 111. 2. 260–278. 10.1016/0039-6028(80)90708-6. 1981. Gorte. R.J.. Schmidt. L.D.. 1981SurSc.111..260G.
  13. Binding States and Decomposition of NO on Single Crystal Planes of Pt. Surface Science. 109. 2. 367–380. 10.1016/0039-6028(81)90494-5. 1981. Gorte. R.J.. Schmidt. L.D.. Gland. John L.. 1981SurSc.109..367G.
  14. The Electron Energy Loss Spectrum of Isocyanic Acid on the Pt(111) Surface. Journal of Catalysis. 67. 2. 387–391. 10.1016/0021-9517(81)90298-0. 1981. Gorte. R..
  15. Amine adsorption in H-ZSM-5. Applied Catalysis. 67. 107–118. 10.1016/S0166-9834(00)84435-8. 1990. Parrillo. D.J.. Adamo. A.T.. Kokotailo. G.T.. Gorte. R.J..
  16. Evidence for low-temperature oxygen migration from ceria to Rh. Journal of Catalysis. 139. 2. 561–567. 10.1006/jcat.1993.1049. 1993. Zafiris. G.S.. Gorte. R.J..
  17. Heats of adsorption for ammonia and pyridine in H-ZSM-5: evidence for identical Brønsted-acid sites. Applied Catalysis A: General. 110. 67–74. 10.1016/0926-860X(94)80106-1. 1994. Parrillo. D.J.. Lee. C.. Gorte. R.J..
  18. Methods for Characterizing Zeolite Acidity. Chemical Reviews. 95. 3. 615–635. 10.1021/cr00035a007. 1995. Farneth. W. E.. Gorte. R. J..
  19. What do we know about the acidity of solid acids?. Catalysis Letters. 62. 1–13. 10.1023/A:1019010013989. 1999. Gorte. R.J.. 85547570 .
  20. Direct Oxidation of hydrocarbons in a solid oxide fuels cell. Nature. 404. 6775. 265–267. 10.1038/35005040. 10749204. 2000. Park. Seungdoo. Vohs. John M.. Gorte. Raymond J.. 2000Natur.404..265P. 4426984 .
  21. Advanced anodes for high-temperature fuel cells. Nature Materials. 3. 1. 17–27. 10.1038/nmat1040. 14704781. 2004. Atkinson. A.. Barnett. S.. Gorte. R. J.. Irvine. J. T. S.. McEvoy. A. J.. Mogensen. M.. Singhal. S. C.. Vohs. J.. 2004NatMa...3...17A. 40574890 .
  22. Web site: UPenn - Raymond Gorte. 2 March 2018.
  23. Web site: Parravano Memorial Award. 2 March 2018.
  24. Web site: AIChE Wilhelm Award. 2 March 2018. 2012-03-28.