催化学报
催化學報
최화학보
CHINESE JOURNAL OF CATALYSIS
2010年
1期
56-60
,共5页
孙德魁%刘振宇%贵国庆%黄张根%刘清雅%肖勇
孫德魁%劉振宇%貴國慶%黃張根%劉清雅%肖勇
손덕괴%류진우%귀국경%황장근%류청아%초용
五氧化二钒%活性炭%氮氧化物%氨%选择性催化还原
五氧化二釩%活性炭%氮氧化物%氨%選擇性催化還原
오양화이범%활성탄%담양화물%안%선택성최화환원
vanadium oxide%activated coke%nitrogen oxide%ammonia%selective catalytic reduction
采用程序升温脱附、在线质谱和原位漫反射红外光谱等手段,比较了NO和NO_2在V_2O_5及V_2O_5/AC催化剂表而的选择催化还原(SCR)反应行为.结果表明,氨以质子态NH_4~+和共价态NH_3分子两种形态吸附于纯V_2O_5表面,V=O为氨的主要吸附活性位.无氧状态下,NO和NO_2皆可与吸附于V_2O_5表面的NH_3反应,并且NO_2与吸附态NH_2的反应活性高于NO.但在V_2O_5/AC催化剂表面,同样在无氧条件下,NO几乎不与吸附态NH_3反应,而NO_2却可以反应并生成N_2.在V_2O_5/AC表面,NO很容易被气相O_2氧化为NO_2,然后参与SCR反应.可见,NO_2是NO在V_2O_5/AC表面发生SCR反应的中间体.
採用程序升溫脫附、在線質譜和原位漫反射紅外光譜等手段,比較瞭NO和NO_2在V_2O_5及V_2O_5/AC催化劑錶而的選擇催化還原(SCR)反應行為.結果錶明,氨以質子態NH_4~+和共價態NH_3分子兩種形態吸附于純V_2O_5錶麵,V=O為氨的主要吸附活性位.無氧狀態下,NO和NO_2皆可與吸附于V_2O_5錶麵的NH_3反應,併且NO_2與吸附態NH_2的反應活性高于NO.但在V_2O_5/AC催化劑錶麵,同樣在無氧條件下,NO幾乎不與吸附態NH_3反應,而NO_2卻可以反應併生成N_2.在V_2O_5/AC錶麵,NO很容易被氣相O_2氧化為NO_2,然後參與SCR反應.可見,NO_2是NO在V_2O_5/AC錶麵髮生SCR反應的中間體.
채용정서승온탈부、재선질보화원위만반사홍외광보등수단,비교료NO화NO_2재V_2O_5급V_2O_5/AC최화제표이적선택최화환원(SCR)반응행위.결과표명,안이질자태NH_4~+화공개태NH_3분자량충형태흡부우순V_2O_5표면,V=O위안적주요흡부활성위.무양상태하,NO화NO_2개가여흡부우V_2O_5표면적NH_3반응,병차NO_2여흡부태NH_2적반응활성고우NO.단재V_2O_5/AC최화제표면,동양재무양조건하,NO궤호불여흡부태NH_3반응,이NO_2각가이반응병생성N_2.재V_2O_5/AC표면,NO흔용역피기상O_2양화위NO_2,연후삼여SCR반응.가견,NO_2시NO재V_2O_5/AC표면발생SCR반응적중간체.
Temperature-programmed desorption, on-line mass spectroscopy, and in situ diffuse reflectance infrared Fourier transform spec-troscopy were preformed to study selective catalytic reduction (SCR) of NO and NO_2 with NH_3 over V_2O_5 and activated carbon (AC)-supported V_2O_5 (V_2O_5/AC). The results show that both protonated (NH4+) and molecularly coordinated (NH_3) ammonia species form on the V_2O_5 surface and V=O bond is the primary active site. Both NO_2 and NO can react with the adsorbed ammonia in the absence of oxy-gen, but the activity of NO_2 is superior to that of NO. On the V_2O_5/AC surface, NO_2 still can react with the adsorbed NH_3 species to form N_2, but NO shows little activity unless oxygen is present. SCR of NO on V_2O_5/AC proceeds through oxidation of NO to NO_2 by oxygen on the AC surface followed by reaction of NO_2 with NH_3 species adsorbed and activated on the V_2O_5 surface .
