C.L. Mangun
J.A. DeBarr
S. Riha
A.A. Lizzio
G.L. Donnals
J. Economy
M. A. Daley
1997
<div id="simple-para.0010">A series of activated carbon fibers (ACFs) and heat-treated oxidized ACFs prepared from phenolic fiber precursors have been studied to elucidate the role of pore size, pore surface chemistry and pore volume for the adsorption of SO<sub>2</sub> and its catalytic conversion to H<sub>2</sub>SO<sub>4</sub>.</div>
<div id="simple-para.0015">For untreated ACFs, the initial rate of SO<sub>2</sub> adsorption from flue gas was shown to be inversely related to pore size. At longer times, the amount of SO<sub>2</sub> adsorbed from flue gas was dependent on both the pore size and pore volume.</div>
<div id="simple-para.0020">Oxidation of the ACFs, using an aqueous oxidant, decreased their adsorption capacity for SO<sub>2</sub> from flue gas due to a decrease in pore volume and repulsion of the SO<sub>2</sub> from acidic surface groups. If these samples were heat-treated to desorb the oxygen containing function groups, the amount of SO<sub>2</sub> adsorption increased. This increase in adsorption capacity was directly correlated to the amount of CO<sub>2</sub> evolved during heat-treatment of the oxidized ACFs. The amount of SO<sub>2</sub> adsorbed for these samples was related to the pore size, pore surface chemistry and pore volume. This analysis is explained in more detail in this paper.</div>
application/pdf
10.1016/S0008-6223(97)89612-1
en
Elsevier
Adsorption of SO<sub>2</sub> onto oxidized and heat-treated activated carbon fibers (ACFs)
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