Formic acid as an alternative reducing agent for the catalytic nitrate reduction in aqueous media 被引量：2

Formic acid as an alternative reducing agent for the catalytic nitrate reduction in aqueous media

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摘要 Formic acid was used for the nitrate reduction as a reductant in the presence of Pd：Cu/γ-alumina catalysts. The surface characteristics of the bimetallic catalyst synthesized by wet impregnation were investigated by SEM, TEM-EDS. The metals were not distributed homogeneously on the surface of catalyst, although the total contents of both metals in particles agreed well with the theoretical values. Formic acid decomposition on the catalyst surface, its influence on solution pH and nitrate removal efficacy was investigated. The best removal of nitrate （50 ppm） was obtained under the condition of 0.75 g/L catalyst with Pd：Cu ratio （4：1） and two fold excess of formic acid. Formic acid decay patterns resembled those of nitrate removal, showing a linear relationship between kf （formic acid decay） and k （nitrate removal）. Negligible amount of ammonia was detected, and no nitrite was detected, possibly due to buffering effect of bicarbonate that is in situ produced by the decomposition of formic acid, and due to the sustained release of H2 gas. Formic acid was used for the nitrate reduction as a reductant in the presence of Pd：Cu/γ-alumina catalysts. The surface characteristics of the bimetallic catalyst synthesized by wet impregnation were investigated by SEM, TEM-EDS. The metals were not distributed homogeneously on the surface of catalyst, although the total contents of both metals in particles agreed well with the theoretical values. Formic acid decomposition on the catalyst surface, its influence on solution pH and nitrate removal efficacy was investigated. The best removal of nitrate （50 ppm） was obtained under the condition of 0.75 g/L catalyst with Pd：Cu ratio （4：1） and two fold excess of formic acid. Formic acid decay patterns resembled those of nitrate removal, showing a linear relationship between kf （formic acid decay） and k （nitrate removal）. Negligible amount of ammonia was detected, and no nitrite was detected, possibly due to buffering effect of bicarbonate that is in situ produced by the decomposition of formic acid, and due to the sustained release of H2 gas.

作者 Eun-kyoung Choi Kuy-hyun Park Ho-bin Lee Misun Cho Samyoung Ahn

机构地区 Department of Environmental Education

出处《Journal of Environmental Sciences》 SCIE EI CAS CSCD 2013年第8期1696-1702,共7页 环境科学学报（英文版）

基金 supported by the Korea Foundation for the Advancement of Science and Creativity under Project URP (2009-04-219) by (in part) Sunchon National University Research Fund in 2012

关键词 formic acid catalytic nitrate reduction Pd：Cu/γ-alumina catalyst H2 supply formic acid catalytic nitrate reduction Pd：Cu/γ-alumina catalyst H2 supply

分类号 O643.32 [理学—物理化学]

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参考文献43

1Barrabes N,Dafinov A,Medina F, Sueiras J E,2010. Catalyticreduction of nitrates using Pt/Ce02 catalysts in a continuousreactor. Catalysis Today, 149(3-4): 341-347.
2Batista J, Pintar A, Ceh M, 1997. Characterization of supportedPd-Cu bimetallic catalysts by SEM, EDXS, AES and cat-alytic selectivity measurements. Catalysis Letters, 43(1-2):79-84.
3Batista J, Pintar A, Gomilsek J, Kodre A, Bomette F, 2001. Onthe structural characteristics of g-alumina-supported PdCubimetallic catalysts. Applied Catalysis A General Split fromApplied Catalysis, 217(1-2): 55-68.
4Bemdt H, Monnicha I,Liicke B, Menzel M, 2001. Tin promotedpalladium catalysts for nitrate removal from drinking water.Applied Catalysis B: Environmental, 30(1-2): 111-122.
5Calvo L, Gilarranz J A, Mohedano A F, Rodriguez J J, 2009. Hy-drodechlorination of 4-chlorophenol in water with formicacid using a Pd/activated carbon catalyst. Journal of Haz-ardous Materials, 161(2-3): 842-847.
6Chaplin B P, Doundy E, Guy K A, Shapley J R, Werth C J, 2006.Effects of natural water ions and humic acid on catalyticnitrate reduction kinetics using an alumina supported Pd-Cucatalyst. Environmental Science Technology, 40(9): 3075-3081.
7Chen Y X, Zhang Y, Chen G H, 2003. Appropriate conditionsor maximizing catalytic reduction efficiency of nitrate intonitrogen gas groundwater. Water Research, 37(10): 2489-2495.
8Columbia M R, Thiel P A, 1994. The interaction of formic acidwith transition metal surfaces, studied in ultrahigh vacuum.Journal of Electroanalytical Chemistry' 369(1-2): 1-14.
9Coq B, Figueras F,2001. Bimetallic palladium catalysts: influ-ence of the co-metal on the catalyst performance. Journalof Molecular Catalysis A: Chemical, 173(1-2): 117-134.
10D’Arino M,Pinna F,Strukul G, 2004. Nitrate and nitrite hy-drogenation with Pd and Pt/Sn02 catalysts: the effect ofthe support porosity and the role of carbon dioxide in thecontrol of selectivity. Applied Catalysis B: Environmental,53(3): 161-168.

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Formic acid as an alternative reducing agent for the catalytic nitrate reduction in aqueous media 被引量：2

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