English
 
Help Privacy Policy Disclaimer
  Advanced SearchBrowse

Item

ITEM ACTIONSEXPORT

Released

Journal Article

Surface chemistry of catalysis by gold

MPS-Authors
/persons/resource/persons242588

Meyer,  Randall J.
Chemical Physics, Fritz Haber Institute, Max Planck Society;

/persons/resource/persons21795

Lemire,  Céline
Chemical Physics, Fritz Haber Institute, Max Planck Society;

/persons/resource/persons22106

Shaikhutdinov,  Shamil K.
Chemical Physics, Fritz Haber Institute, Max Planck Society;

/persons/resource/persons21524

Freund,  Hans-Joachim
Chemical Physics, Fritz Haber Institute, Max Planck Society;

External Resource
No external resources are shared
Fulltext (restricted access)
There are currently no full texts shared for your IP range.
Fulltext (public)
There are no public fulltexts stored in PuRe
Supplementary Material (public)
There is no public supplementary material available
Citation

Meyer, R. J., Lemire, C., Shaikhutdinov, S. K., & Freund, H.-J. (2004). Surface chemistry of catalysis by gold. Gold Bulletin, 37(1-2), 72-124. doi:10.1007/BF03215519.


Cite as: https://hdl.handle.net/11858/00-001M-0000-0011-0C64-1
Abstract
Gold has long been regarded as an "inert" surface and bulk gold surfaces do not chemisorb many molecules easily. However, in the last decade, largely through the efforts of Masatake Haruta, gold particles, particularly those below 5 nm in size, have begun to garner attention for unique catalytic properties (1-8). In recent years, supported gold particles have been shown to be effective as catalysts for low temperature CO oxidation (9), selective oxidation of propene to propene oxide (10), water gas shift (11), NO reduction (12). selective hydrogenation of acetylene (or butadiene) (13) and other reactions (1-5,14-16). Currently used in Japanese toilets for odour reduction (3), gold has demonstrated industrial potential as well for the hydrochlorination of ethyne to vinyl chloride (16-18) and as a bimetallic component of vinyl acetate monomer production catalysts (19,20). Low temperature CO oxidation is of particular importance, finding applications in indoor air quality applications (21) and as a guard bed catalyst to prevent CO poisoning of proton exchange membrane fuel cells (22-24).