基本介紹
- 中文名:程傑
- 民族:漢族
- 畢業院校:中科院生態環境研究中心
- 學位/學歷:博士/研究生
- 職業:科研人員
- 研究方向:工業污染減排
研究領域,科研項目,代表性論著,
研究領域
主要研究領域為環境材料和工業污染物催化控制的套用基礎研究,在揮發性有機物VOCs污染控制材料、轉化反應機理、減排控制民您海危技術等方面進行了比較察戒承系統的研究與開發工作,取得了系列創新性研究成果,形成了多項污染控制材料與控制技術並進行規模化工業套用。
科研項目
(1) 國家自然科學基金促辯察面上項目, 含氯揮發性有機化合物催化氧化過程研究,2017-2020
(2) 北京市科委課題拒趨姜,低氮燃燒與揮發性有機物高效淨化技術,2018-2021
(3) 大氣重污染成因與治理攻關項目課題雅煉紋企,VOCs重點行業排放特徵及減排監管技術體系研究,2017-2019
(4) 國家自然科學基金面上項目,分子篩材料上含氮有機物催化氧化研究,2015-2018
(5) 環保公益課題,重點行業VOCs減排技術評估與管理體系習牛全研究,2013-2014
代表性論著
(1) 論文成果
[1] Distribution and formation mechanisms of polychlorinated organic byproducts upon the catalytic oxidation of
1,2-dichlorobenzene with palladium-loaded catalysts. Journal of Hazardous Materials 2020, 393, 122412.
[2] Yolk-shell-like mesoporous CoCrOx with superior activity andchlorine resistance in dichloromethane
destructionn. Applied Catalysis B-Environmental 2020, 264, 118493.
[3] Selective catalytic oxidation of n-butylamine over Cu-zeolite catalysts. Catalysis Today 2020, 339, 192–199.
[4] Recent advances in the catalytic oxidation of volatile organic compounds: A review based on pollutant sorts
and sources. Chemical Reviews 2019, 119, 4471-4568.
[5] Hydrotalcite-derived CuxMg3−xAlO oxides for catalytic degradation of n‑butylamine with low concentration
NO and pollutant destruction mechanism, Industrial & Engineering Chemistry Research 2019, 58, 9362−9371.
[6] Highly efficient removal of organic pollutants by ultrahigh-surface-area-ethynylbenzene-based conjugated
microporous polymers via adsorption–photocatalysis synergy, Catalysis Science &承臘 Technology 2018, 8,5024-5033.
[7] Synthesis, characterization and evaluations of the Ag/ZSM-5 for ethyleneoxidation at room temperature:
Investigating the effect of water and deactivation. Chemical Engineering Journal 2018, 347, 808-818.
[8] Efficient capture of CO2 over ordered micro-mesoporous hybridcarbon nanosphere. Applied Surface Science
2018, 439, 113–121.
[9] Fluorine-enhanced Pt/ZSM-5 catalysts for low-temperature oxidation of ethylene. Catalysis Science &
Technology 2018, 8 (7), 1988-1996.
[10] Understanding the active sites of Ag/Zeolites and deactivation mechanism of ethylene catalytic oxidation at
room temperature. ACS Catalysis 2018, 8(2), 1248-1258.
(2) 專利成果
[1] 一種處理揮發性氯代芳烴污染物的方法及催化劑,201811120312.0
[2] 一種處理含氮揮發性有機污染物的催化劑及方法,201811184190.1
[3] 一種有機廢氣處理裝置,201821654487.5
NO and pollutant destruction mechanism, Industrial & Engineering Chemistry Research 2019, 58, 9362−9371.
[6] Highly efficient removal of organic pollutants by ultrahigh-surface-area-ethynylbenzene-based conjugated
microporous polymers via adsorption–photocatalysis synergy, Catalysis Science & Technology 2018, 8,5024-5033.
[7] Synthesis, characterization and evaluations of the Ag/ZSM-5 for ethyleneoxidation at room temperature:
Investigating the effect of water and deactivation. Chemical Engineering Journal 2018, 347, 808-818.
[8] Efficient capture of CO2 over ordered micro-mesoporous hybridcarbon nanosphere. Applied Surface Science
2018, 439, 113–121.
[9] Fluorine-enhanced Pt/ZSM-5 catalysts for low-temperature oxidation of ethylene. Catalysis Science &
Technology 2018, 8 (7), 1988-1996.
[10] Understanding the active sites of Ag/Zeolites and deactivation mechanism of ethylene catalytic oxidation at
room temperature. ACS Catalysis 2018, 8(2), 1248-1258.
(2) 專利成果
[1] 一種處理揮發性氯代芳烴污染物的方法及催化劑,201811120312.0
[2] 一種處理含氮揮發性有機污染物的催化劑及方法,201811184190.1
[3] 一種有機廢氣處理裝置,201821654487.5
