The effect of the active carbonyl groups and residual acid on the ammonia adsorption over the acid-modified activated carbon
Chang Ming Li, Shuying Zhao, Ming Li, Zhiliang Yao, Yang Li, Chuanqiang Zhu, Simin Xu, Junjie Li, Jian Yu
Abstract
The deep insight into the adsorption mechanism of ammonia (NH3) over acid-modified activated carbon will be of great significance to develop more efficient carbon materials for NH3 adsorption. In this work, a co-adsorption mechanism of NH3 and residual nitric acid (HNO3) on the active carboxyl site is proposed to elaborate the enhanced NH3 adsorption capacity over the acid-modified activated carbon based on both the experimental and density functional theory (DFT) results. The adsorption behaviors of NH3 over the different acid-modified activated carbon samples show that the activated carbon modified by 10 M HNO3 at 90 ºC possesses the best NH3 adsorption capacity (40 mg/g), and the residual HNO3 can be observed with the release of both NOx and NH3 during the heat treatment of the used HNO3-modified activated carbon. The multiple structural characterizations reveal that the activated carbon can be oxidized and etched by HNO3 with enriched pore structure and oxygen-containing functional groups, and acidic functional groups play a key role in the improved NH3 adsorption capacity. DFT calculations further display that the carboxyl functional group can strongly interplay with NH3 or HNO3 with the lowest adsorption energy (-0.66 eV and -0.79 eV, respectively), and the co-adsorption of NH3 and HNO3 around the carboxyl functional group forms a strong circular hydrogen-bond network among NO3−, NH4+ and carbonyl and further decreases the adsorption energy (-1.63 eV). The experimental and theoretical results together demonstrate that the oxidation and etching of activated carbon by acid enrich the active surface carboxyl functional groups, and the co-adsorption of NH3 with the residual HNO3 around the carboxyl functional group through the strong circular hydrogen-bond network accounts for the enhanced NH3 adsorption capacity of the acid-modified activated carbon.