(113d) Palladium Sorbents for High Temperature Capture of Mercury, Arsenic, Selenium and Phosphorus from Fuel Gas | AIChE

(113d) Palladium Sorbents for High Temperature Capture of Mercury, Arsenic, Selenium and Phosphorus from Fuel Gas

Authors 

Pennline, H. W. - Presenter, U.S. Department of Energy, National Energy Technology Laboratory
Stanko, D. - Presenter, National Energy Technology Laboratory
Baltrus, J. P. - Presenter, National Energy Technology Laboratory
Hamilton, H. - Presenter, Johnson Matthey Technology Centre
Roswell, L. - Presenter, Johnson Matthey Technology Centre
Poulston, S. - Presenter, Johnson Matthey Technology Centre
Smith, A. - Presenter, Johnson Matthey Technology Centre
Chu, W. - Presenter, Johnson Matthey


In gasification for power generation, the removal of mercury by sorbents at elevated temperatures preserves the high thermal efficiency of the integrated gasification combined cycle system. Unfortunately, most sorbents will display poor capacity for elemental mercury at elevated temperatures. Previous experience with sorbents in flue gas has allowed for judicious selection of potential high temperature candidate sorbents. The capacities of many sorbents for elemental mercury from nitrogen, as well as from different simulated fuel gases at temperatures from 400 -700°F, were determined. The simulated fuel gas compositions contain varying concentrations of mercury, arsine, hydrogen selenide, phosphine, carbon monoxide, hydrogen, carbon dioxide, moisture, and hydrogen sulfide.

Palladium is an attractive sorbent candidate for the removal of mercury from fuel gases at elevated temperatures. In addition, recent results suggest that palladium also has excellent potential for arsenic, phosphorus and selenium capture from fuel gases, making it capable of multi-pollutant capture. A license agreement has been signed by the United States Department of Energy and Johnson Matthey for further development of the sorbents. Future sorbent development for trace metal capture from fuel gases will be discussed.