彭悦-pg麻将胡了模拟器链接

2009–2012      吉林大学   物理学院    博士

2006–2009      吉林大学   原子分子物理研究所   硕士

2017–              清华大学    环境学院    副研究员

2014–2017      美国佐治亚理工学院    博士后

2012–2014      清华大学    环境学院    博士后

est, acb等十多个sci期刊审稿人

大气污染控制

环保功能材料的密度泛函计算

中国 环境保护科学技术奖 环保部 一等奖 2014

中国 科学技术奖 中国循环经济协会 二等奖 2014

期刊文章

2017年：

[1] h. zhang, y. zou, y. peng*, influence of sulfation on ceo2-zro2 catalysts for no reduction with nh3, chin. j. catal., 38 (2017) 160-167.

[2] x. li, c. liu, x. li, y. peng*, j. li*, a neutral and coordination regeneration method of ca-poisoned v2o5-wo3/tio2 scr catalyst, catal. commun., 100 (2017) 112-116.

[3] t. zhang, f. qiu, h. chang, y. peng*, j. li*, novel w-modified snmnceox catalyst for the selective catalytic reduction of nox with nh3, catal. commun., 100 (2017) 117-120.

2016年：

[1] y. peng, w. si, x. li, j. luo, j. li*, j. crittenden*, j. hao, comparison of moo3 and wo3 on arsenic poisoning v2o5/tio2 catalyst: drifts and dft study, appl. catal. b, 181 (2016) 692-698.

[2] y. peng, w. si, j. luo, w. su, h. chang, j. li*, j. hao and j. crittenden*, surface tuning of la0.5sr0.5coo3 perovskite catalysts by acetic acid for nox storage and reduction, environ. sci. technol., 50 (2016) 6442-6448.

[3] y. peng, w. si, x. li, j. chen, j. li*, j. crittenden*, j. hao, investigation of the poisoning mechanism of lead on the ceo2-wo3 catalyst for the nh3-scr reaction via in situ ir and raman spectroscopy measurement, environ. sci. technol., 50 (2016) 9576-9582.

[4] r. qu, y. peng, x. sun, j. li*, x. gao*, k. cen, identification of the reaction pathway and reactive species for the selective catalytic reduction of no with nh3 over cerium-niobium oxide catalysts, catal. sci. technol., 6 (2016) 2136-2142.

[5] x. li, j. li*, y. peng, h. chang, t. zhang, s. zhao, w. si, j. hao, mechanism of arsenic poisoning on scr catalyst of cew/ti and its novel efficient regeneration method with hydrogen, appl. catal. b, 184 (2016) 246-257.

[6] y. qian, x. guo, y. zhang, y. peng, p. sun, c. huang, j. niu, x. zhou*, j. crittenden*, perfluorooctanoic acid degradation using uv-persulfate process: modeling of the degradation and chlorate formation, environ. sci. technol., 50 (2016) 772-781.

[7] j. li*, y. peng, h. chang, x. li, j. crittenden, j. hao, chemical poison and regeneration of scr catalysts for nox removal from stationary sources, front. environ. sci. eng., 10 (2016) 413-427.

[8] x. liu, j. li*, x. li, y. peng, h. wang, x. jiang, l. wang, nh3 selective catalytic reduction of no: a large surface tio2 support and its promotion of v2o5 dispersion on the prepared catalyst, chin. j. catal., 37 (2016) 878-887.

[9] x. li, j. li*, y. peng, x. li, k. li, j. hao, comparison of the structures and mechanism of arsenic deactivation of ceo2–moo3 and ceo2–wo3 scr catalysts, j. phys. chem. c, 120 (2016) 18005-18014.

2015年：

[1] y. peng, w. yu, w. su, x. huang, j. li*, an experimental and dft study of the adsorption and oxidation of nh3 on a ceo2 catalyst modified by fe, mn, la and y, catal. today, 242, part b (2015) 300-307.

[2] y. peng, j. li*, w. si, j. luo, y. wang, j. fu, x. li, j. crittenden*, j. hao, deactivation and regeneration of a commercial scr catalyst: comparison with alkali metals and arsenic, appl. catal. b, 168-169 (2015) 195-202.

[3] y. peng, j. li*, w. si, x. li, w. shi, j. luo, j. fu, j. crittenden*, and j. hao, ceria promotion on the potassium resistance of mnox/tio2 scr catalysts: an experimental and dft study, chem. eng. j., 269 (2015) 44-50.

[4] y. peng, w. si, j. li*, j. crittenden*, and j. hao, experimental and dft study on sr doped lamno3 catalyst for nox storage and reduction, catal. sci. technol., 5 (2015) 2478-2485.

[5] q. wang, y. peng, j. fu*, g. kyzas, s. billah, s. an*, synthesis, characterization, and catalytic evaluation of co3o4/γ-al2o3 as methane combustion catalysts: significance of co species and the redox cycle, appl. catal. b, 168–169 (2015) 42-50.

[6] w. su, h. chang, y. peng, c. zhang, j. li*, reaction pathway investigation on the selective catalytic reduction of no with nh3 over cu/ssz-13 at low temperatures, environ. sci. technol., 49 (2015) 467-473.

[7] x. huang, y. peng, x. liu, k. li, y. deng*, j. li*, the promotional effect of moo3 doped v2o5/tio2 for chlorobenzene oxidation, catal. commun., 69 (2015) 161-164.

[8] y. shao, j. li*, h. chang, y. peng, y. deng*, the outstanding performance of the ldhs-derived mixed oxide mn/coalox for hg0 oxidation, catal. sci. technol., 5 (2015) 3536-3544.

[9] w. si, y. wang, y. peng, j. li*, selective dissolution of a-site cations in abo3 perovskites: a new path to high-performance catalysts, angew. chem. int. ed., 127 (2015) 8065-8068.

[10] w. si, y. wang, y. peng, x. li, k. li, j. li*, a high-efficiency γ-mno2-like catalyst in toluene combustion, chem. commun., 51 (2015) 14977-14980.

[11] j. luo, x. luo, j. crittenden*, j. qu*, y. bai, y. peng, j. li, removal of antimonite (sb(iii)) and antimonate (sb(v)) from aqueous solution using nanofibers that are decorated with zirconium oxide (zro2), environ. sci. technol., 49 (2015) 11115-11124.

[12] x. li, j. li*, y. peng, w. si, x. he, j. hao, regeneration of commercial scr catalysts: probing the existing forms of arsenic oxide, environ. sci. technol., 49 (2015) 9971-9978.

[13] w. su, z. li, y. peng, j. li*, correlation of the changes in the framework and active cu sites for typical cu/cha zeolites (ssz-13 and sapo-34) during hydrothermal aging, phys. chem. chem. phys., 17 (2015) 29142-29149.

[14] y. xia, q. dai*, m. weng, y. peng, j. luo, x. meng, x. luo, j. chen, j. crittenden, fabrication and electrochemical treatment application of an al-doped pbo2 electrode with high oxidation capability, oxygen evolution potential and reusability, j. electrochem. soc., 162 (2015) 258-262.

[15] z. li, j. li*, s. liu, x. ren, j. ma, w. su, y. peng, ultra hydrothermal stability of ceo2-wo3/tio2 for nh3-scr of no compared to traditional v2o5-wo3/tio2 catalyst, catal. today, 258, part 1 (2015) 11-16.

[16] x. sun, r. qu, y. lei, b. bai, h. chang, y. peng, w. su, c. zhang, j. li*, lean nox–sno2–ceo2 catalyst at low temperatures, catal. today, 258, part 2 (2015) 556-563.

[17] x. li, j. li*, y. peng, t. zhang, s. liu, j. hao, selective catalytic reduction of no with nh3 over novel iron-tungsten mixed oxide catalyst in a broad temperature range, catal. sci. technol., 5 (2015) 4556-4564.

2014年：

[1] y. peng, c. wang, j. li*, structure-activity relationship of vox/ceo2 nanorod for no removal with ammonia, appl. catal. b, 144 (2014) 538-546.

[2] y. peng, j. li*, x. huang, x. li, w. su, x. sun, d. wang, j. hao, deactivation mechanism of potassium on the v2o5/ceo2 catalysts for scr reaction: acidity, reducibility and adsorbed-nox, environ. sci. technol., 48 (2014) 4515-4520.

[3] y. peng, j. li*, w. si, j. luo, q. dai, x. luo, x. liu, j. hao, insight into deactivation of commercial scr catalyst by arsenic: an experiment and dft study, environ. sci. technol., 48 (2014) 13895-13900.

[4] x. zhang, z. li, y. peng, w. su, x. sun, j li*, investigation on a novel cao-y2o3 sorbent for efficient co2 mitigation, chem. eng. j., 136-137 (2014) 19-28.

[5] h. arandiyan, y. peng, c. liu, h. chang, j. li*, effects of noble metals doped on mesoporous laalni mixed oxide catalyst and identification of carbon deposit for reforming ch4 with co2, j. chem. technol. & biotechnol., 89 (2014) 372-381.

[6] s. yang*, s. xiong, y. liao, x. xiao, f. qi, y. peng, y. fu, w. shan, j. li*, mechanism of n2o formation during the low-temperature selective catalytic reduction of no with nh3 over mn–fe spinel, environ. sci. technol., 48 (2014) 10354-10362.

2013年：

[1] y. peng, j. li*, ammonia adsorption on graphene and graphene oxide: a first-principles study, front. environ. sci. eng., 7 (2013) 403-411.

[2] y. peng, c. liu, x. zhang, j. li*, the effect of sio2 on a novel ceo2–wo3/tio2 catalyst for the selective catalytic reduction of no with nh3, appl. catal. b, 140-141 (2013) 276-282.

[3] y. peng, k. li, j. li*, identification of the active sites on ceo2–wo3 catalysts for scr of nox with nh3: an in situ ir and raman spectroscopy study, appl. catal. b, 140-141 (2013) 483-492.

[4] y. peng, r. qu, x. zhang, j. li*, the relationship between structure and activity of moo3-ceo2 catalysts for no removal: influences of acidity and reducibility, chem. commun., 49 (2013) 6215-6217.

[5] j. chen, x. zhang, h. arandiyan, y. peng, h. chang, j. li*, low temperature complete combustion of methane over cobalt chromium oxides catalysts, catal. today, 201 (2013) 12-18.

[6] c. liu, s. yang, l. ma, y. peng, h. arandiyan, h. chang, j. li*, comparison on the performance of α-fe2o3 and γ-fe2o3 for selective catalytic reduction of nitrogen oxides with ammonia, catal. lett., 143 (2013) 697-704.

[7] c. wang, s. yang, h. chang, y. peng, j. li*, dispersion of tungsten oxide on scr performance of v2o5-wo3/tio2: acidity, surface species and catalytic activity, chem. eng. j., 225 (2013) 520-527.

[8] c. wang, s. yang, h. chang, y. peng, j. li*, structural effects of iron spinel oxides doped with mn, co, ni and zn on selective catalytic reduction of no with nh3, j. mol. catal. a, 376 (2013) 13-21.

[9] h. arandiyan, h. chang, c. liu, y. peng, j. li*, dextrose-aided hydrothermal preparation with large surface area on 1d single-crystalline perovskite la0.5sr0.5coo3 nanowires without template: highly catalytic activity for methane combustion, j. mol. catal. a, 378 (2013) 299-306.

[10] s. yang, y. guo, h. chang, l. ma, y. peng, z. qu, n. yan*, c. wang, j. li*, novel effect of so2 on the scr reaction over ceo2: mechanism and significance, appl. catal. b, 136-137 (2013) 19-28.

[11] c. liu, l. chen, h. chang, l. ma, y. peng, h. arandiyan, j. li*, characterization of ceo2–wo3 catalysts prepared by different methods for selective catalytic reduction of nox with nh3, catal. comm., 40 (2013) 145-148.

2012年：

[1] y. peng, z. liu, x. niu, l. zhou, c. fu, h. zhang, j. li*, w. han*, manganese doped ceo2–wo3 catalysts for the selective catalytic reduction of nox with nh3: an experimental and theoretical study, catal. commun., 19 (2012) 127-131.

[2] y. peng, j. li*, l. chen, j. chen, j. han, h. zhang, w. han*, alkali metal poisoning of a ceo2-wo3 catalyst used in the selective catalytic reduction of nox with nh3: an experimental and theoretical study, environ. sci. technol., 46 (2012) 2864-2869.

[3] y. peng, j. li*, w. shi, j. xu, j. hao, design strategies for development of scr catalyst: improvement of alkali poisoning resistance and novel regeneration method, environ. sci. technol., 46 (2012) 12623-12629.

[4] s. yang, c. wang, j. chen, y. peng, l. ma, h. chang, l. chen, c. liu, j. xu, j. li*, n. yan*, a novel magnetic fe-ti-v spinel catalyst for the selective catalytic reduction of no with nh3 in a broad temperature range, catal. sci. technol., 2 (2012) 915-917.

[5] s. yang, j. li*, c. wang, j. chen, l. ma, h. chang, l. chen, y. peng, n. yan*, fe–ti spinel for the selective catalytic reduction of no with nh3: mechanism and structure–activity relationship, appl. catal. b, 117-118 (2012) 73-80.

[6] y. dai, j. li*, y. peng, x. tang, effects of mno2 crystal structure and surface property on the nh3-scr reaction at low temperature, acta physico-chimica sinica, 28 (2012) 1771-1776.

专利：

1.发明专利：高温选择性催化还原nox催化剂及其制备方法，专利号：201010592107.1，专利人：韩炜，李骏，韩建，张贺，彭悦，张克金，张苡铭

2.发明专利：中低温环境下选择性催化还原氮氧化物的催化剂，专利号：201110088471.9，专利人：韩炜，张克金，彭悦，张苡铭，曹雅彬，张贺，韩建，周亮

3.发明专利：一种有效抑制so2氧化的脱硝催化剂的制备方法，专利号：201410153821.9，专利人：李俊华，彭悦，李柯志，郝吉明

4.发明专利：用于宽温度窗口高硫条件下的脱硝催化剂及其制备方法，专利号：201410768763.0，专利人：李俊华，彭悦，李柯志，刘欣，郝吉明

5.发明专利：一种应用于高温烟气条件下的脱硝催化剂及其制备方法，专利号：20140765626.1，专利人：李俊华，刘彩霞，彭悦，刘欣，郝吉明

6.发明专利：一种低温烟气脱硝的催化剂成型工艺，专利号：201410427461.7，专利人：李俊华，黄旭，彭悦，关立军，王子藤，郝吉明，何亮，王明飞

7.实用新型专利：一种用于低温烟气脱硝的环形scr反应器，专利号：201420614789.5，专利人：李俊华，黄旭，彭悦，关立军，王子藤，郝吉明

8.实用新型专利：一种用于低温烟气脱硝的箱式侧流反应器，专利号：201420614774.9，专利人：李俊华，黄旭，彭悦，关立军，王子藤，郝吉明