個人簡歷

教育簡歷

• 2001-2006, 加州大學河邊分校，化學系，博士

• 1998-2001, 沐鸣2平台，化學系，碩士

• 1994-1998, 沐鸣2平台💜🛡，化學系♋️，學士

工作簡歷

• 2013.12-至今🪹，   沐鸣2平台，環境系🧑🏼‍🏫🥟，教授

• 2009.12-2013.12  沐鸣2平台，環境系，副研究員

• 2006.05-2009.10  橡樹嶺國家實驗室，化學科學部門😼，博士後

博士生導師/方向

• 環境工程（環境催化）

碩士生導師/方向

• 環境工程（環境催化）

榮譽與獎勵

【2010】Journal of Physical Chemistry top 20% reviewer

【2011】第二屆全國科學博客大賽教育求學組優秀博客大獎（馬博士-馬臻-科學網）

【2011】第二屆全國科學博客大賽海外觀察組優秀博文大獎（《談談在美國讀研的科研情況》）

【2011】第二屆全國科學博客大賽入圍博文紀念獎（《我所經歷的一種美國博士生培養方式》）

【2011】第三屆中國科技館杯“我與科協”征文活動紀念獎（《寫博客成了欄目主持人》）

【2011】2010-2011學年復旦學院“經典讀書計劃”讀書小組風采獎（《生命中不該忘記的事》指導教師）

【2012】2011-2012學年復旦學院“經典讀書計劃”讀書小組風采獎（《生命中不該忘記的事》指導教師）

【2014】《科技導報》2013年度優秀欄目主持人

【2016】沐鸣2平台2016屆本（專）科生“我心目中的好老師”提名獎

【2018】沐鸣2开户2016-2017學年教學優秀獎

【2018】《催化學報》優秀審稿專家

【2018】沐鸣2平台六屆五次教代會優秀提案獎三等獎（《關於加強校報建設的提案》

【2018】首屆九三教育論壇征文一等獎（《研究生培養和大學教師發展的幾個問題》）

【2018】沐鸣2平台2018年度校園網絡文化作品網文類三等獎（《做科研的難點和樂趣》）

【2019】沐鸣2开户2017-2018學年教學優秀獎

【2019】沐鸣2平台2019年度校園網絡文化作品網文類一等獎（《全面把握、因勢利導🥦：辯證地看待高校“網紅教師”現象》）

【2019】沐鸣2平台2019年度最受歡迎教師運營新媒體（馬臻的博客）

【2020】沐鸣2平台第九屆“研究生心目中的好導師”提名獎

【2020】第六屆中國化學會《化學通報》優秀編審獎

【2020】九三學社上海市委思想政治建設暨宣傳骨幹網絡培訓班優秀學員

【2020】2020年《中國研究生》雜誌優秀特邀撰稿人

【2020】中國學位與研究生教育學會先進工作者（2019-2020）

【2021】2021年長三角科學道德和學風建設論壇“特色工作法案例”類征文二等獎（《研究生導師立德樹人機製建設》）

【2021】第二屆九三教育論壇征文二等獎（《全面把握、因勢利導😭：辯證地看待高校“網紅教師”現象》）

學術論文

2021年

[191] Z. Ma*, Hydroxyapatite-based catalysts: Influence of the molar ratio of Ca to P, in: Design and Application of Hydroxyapatite-Based Catalysts, D.P. Min (ed.), Wiley-VCH, Weinheim, in press.

[190] Y.F. Liu, Z. Ma*, Combining g-C3N4 with CsPbI3 for efficient photocatalysis under visible light, Colloids and Surfaces A: Physicochemical and Engineering Aspects 618 (2021) 127310 (11 pp).

[189] H.Y. Xue, X.M. Guo*, T. Meng, D.S. Mao, Z. Ma*, Poisoning effect of K with respect to Cu/ZSM-5 used for NO reduction, Colloid and Interface Science Communications 44 (2021) 100465 (9 pp).

[188] Y.H. Chen, Y.F. Liu, Z. Ma*, g-C3N4 sensitized by an indoline dye for photocatalytic H2 evolution, Processes 9 (2021) 1055 (15 pp).

[187] Y.N. Liang, D.S. Mao*, X.M. Guo, J. Yum G.S. Wu, Z. Ma*, Solvothermal preparation of CuO-ZnO-ZrO2 catalysts for methanol synthesis via CO2 hydrogenation, Journal of the Taiwan Institute of Chemical Engineers 121 (2021) 83-93.

[186] Y.F. Liu, Z. Ma*, TiOF2/g-C3N4 composite for visible-light driven photocatalysis, Colloids and Surfaces A: Physicochemical and Engineering Aspects 618 (2021) 126471 (12 pp).

[185] X.L. Hu, J.X. Chen, W.Y. Qu, R. Liu, D.R. Xu, Z. Ma, X.F. Tang*, Sulfur-resistant ceria-based low-temperature SCR catalysts with the non-bulk electronic states of ceria, Environmental Science & Technology 55 (2021) 5435-5441.

[184] Y.F. Liu, Z. Ma*, g-C3N4 modified by pyropheophorbide-a for photocatalytic H2 evolution, Colloids and Surfaces A: Physicochemical and Engineering Aspects 615 (2021) 126128 (7 pp).

[183] Y.H. Chen, Y.F. Liu, Z. Ma*, Graphitic C3N4 modified by Ru(II)-based dyes for photocatalytic H2 evolution, Colloids and Surfaces A: Physicochemical and Engineering Aspects 614 (2021) 126119 (10 pp).

[182] Y.X. Chen, Z. Ma, X.F. Tang*, Single-atom heterogeneous catalysts, in: Heterogeneous Catalysts: Emerging Techniques for Design, Characterization and  Applications, W.Y. Teoh, A. Urakawa, Y.H. Ng, P.H.L. Sit (eds.), Wiley-VCH, Weinheim (2021) 103-117.

2020年（12篇）

[181] Y.F. Liu, Z. Ma*, g-C3N4 modified by meso-tetrahydroxyphenylchlorin for photocatalytic hydrogen evolution under visible/near-infrared light, Frontiers in Chemistry 8 (2020) 605343 (13 pp).

[180] 丁雨陽, 劉振東, 馬臻*, Ag3VO4/Ag2Mo2O7復合光催化劑, 復旦學報(自然科學版) 59 (2020) 618-626.

[179] Y. Chen, Y.M. Liu, D.S. Mao*, J. Yu, Y.L. Zheng, X.M. Guo, Z. Ma*, Facile cyclodextrin-assisted synthesis of highly active CuO-CeO2/MCF catalyst for CO oxidation, Journal of the Taiwan Institute of Chemical Engineers 113 (2020) 16-26.

[178] Z.D. Liu, Z. Ma*, Promoting the photocatalytic activity of Bi4Ti3O12 microspheres by incorporating iron, RSC Advances 10 (2020) 19232-19239.

[177] Y.F. Liu, S.F. Kang*, L.F. Cui*, Z. Ma*, Boosting near-infrared-driven photocatalytic H2 evolution using protoporphyrin-sensitized g-C3N4, Journal of Photochemistry and Photobiology A: Chemistry 396 (2020) 112517 (9 pp).

[176] L. Wang, J.B. Wang, X.N. Liu, Y.X. Chen, H.P. Cheng, Y.B. Wu, H. Pei, Z. Ma*, FeCeOx with improved activity for catalytic reduction of NO with NH3, Journal of Physics and Chemistry of Solids 142 (2020) 109472 (8 pp).

[175] 丁雨陽, 劉振東, 焦鐘藝, 馬臻*, AgI/Ag2Mo2O7和AgBr/Ag2Mo2O7復合光催化劑, 復旦學報(自然科學版) 59 (2020) 97-108 & 115.

[174] L.L. Liu, X.Y. Yang, Y.J. Xie, H. Liu, X.R. Zhou, X.Y. Xiao, Y. Ren, Z. Ma, X.W. Cheng, Y.H. Deng*, D.Y. Zhao, A universal lab-on-salt-particle approach to 2D single-layer ordered mesoporous materials, Advanced Materials 32 (2020) 1906653 (9 pp).

[173] X.L. Hu, J.X. Chen, S.Y. Li, Y.X. Chen, W.Y. Qu, Z. Ma, X.F. Tang*, The promotional effect of copper in catalytic oxidation by Cu-doped α-MnO2 nanorods, Journal of Physical Chemistry C 124 (2020) 701-708.

[172] X.L. Hu, S.Y. Li, Y.X. Chen, W.Y. Qu, J.X. Chen, Z. Ma, X.F. Tang*, Single-ion copper doping greatly enhances catalytic activity of manganese oxides via electronic interactionsin, Chemical Communications 56 (2010) 904-907.

[171] J. Liu, Z.D. Liu, J.L. Zhang, Z. Ma*, AgI/Ag2Mo3O10·1.8H2O: A new photocatalyst working under visible light, Materials Chemistry and Physics 241 (2020) 122406 (10 pp).

[170] Y.F. Liu, M.F. He, R. Guo, Z.R. Fang, S.F. Kang*, Z. Ma, M.D. Dong, W.L. Wang*, L.F. Cui*, Ultrastable metal-free near-infrared-driven photocatalysts for H2 production based on protonated 2D g-C3N4 sensitized with Chlorin e6, Applied Catalysis B: Environmental 260 (2020) 118137 (10 pp).

2019年（10篇）

[169] K. Xie, D.R. Xu, C. Li, X.N. Liu, X.L. Hu, Z. Ma, X.F. Tang, Y.X. Chen*, Low-temperature benzene abatement over active manganese oxides with abundant catalytic sites, Industrial & Engineering Chemistry Research 58 (2019) 3717601-17607.

[168] C. Li, Z.W. Huang, X.N. Liu, J.X. Chen, W.Y. Qu, X.M. Jiang, H. Wang, Z. Ma, X.F. Tang, Y.X. Chen*, Rational design of alkali-resistant catalysts for selective NO reduction with NH3, Chemical Communications 55 (2019) 9853-9856.

[167] Z.D. Liu, Z. Ma*, Ag-SrTiO3/TiO2 composite nanostructures with enhanced photocatalytic activity, Materials Research Bulletin 118 (2019) 110492 (9 pp).

[166] Z.D. Liu, Z. Ma*, Facile synthesis of Bi2S3/BiOCl0.5Br0.5 microspheres with enhanced photocatalytic activity under visible light irradiation, Journal of the Taiwan Institute of Chemical Engineers 100 (2019) 220-229.

[165] Z.Y. Jiao, Z.D. Liu, Z. Ma*, Rodlike AgI/Ag2Mo2O7 heterojunctions with enhanced visible-light-driven photocatalytic activity, ACS Omega 4 (2019) 7919-7930.

[164] S. Liu, H.B. Zhou, L. Zhang, Z. Ma*, Y.D. Wang*, Activated carbon supported Mo-Co-K sulfide catalysts for synthesizing higher alcohols from CO2, Chemical Engineering & Technology 42 (2019) 962-970.

[163] J.L. Zhang, Z.D. Liu, Z. Ma*, Facile formation of Bi2O2CO3/Bi2MoO6 nanosheets for visible-light-driven photocatalysis, ACS Omega 4 (2019) 3871-3880.

[162] Z.D. Liu, X.N. Liu, Q.F. Lu, Q.Y. Wang, Z. Ma*, TiOF2/TiO2 composite nanosheets: Effect of hydrothermal synthesis temperature on physicochemical properties and photocatalytic activity, Journal of the Taiwan Institute of Chemical Engineers 96 (2019) 165-173.

[161] 王玉琳, 劉歡, 馬臻*, 六方相和單斜相LaPO4負載金催化劑的CO氧化, 復旦學報(自然科學版) 58 (2019) 109-119.

[160] Z.Y. Jiao, J.L. Zhang, Z.D. Liu, Z. Ma*, Ag/AgCl/Ag2MoO4 composites for visible-light-driven photocatalysis, Journal of Photochemistry and Photobiology A: Chemistry 371 (2019) 67-75.

2018年（16篇）

[159] Y.L. Wang, H. Liu, Z. Ma*, Cerium phosphate-supported Au catalysts for CO oxidation, Chinese Journal of Chemical Engineering 26 (2018) 2055-2063.

[158] J.X. Chen, W.Y. Qu, Y.X. Chen, X.N. Liu, X.M. Jiang, H. Wang, Y.H. Zong, Z. Ma, X.F. Tang*, Simultaneously enhancing stability and activity of maghemite via site-specific Ti(IV) doping for NO emission control, ChemCatChem 10 (2018) 4683-4688.

[157] X.N. Liu, J.Y. Gao, Y.X. Chen, C. Li, J.X. Chen, W.Y. Qu, X. Chen, Z. Ma, X.F. Tang*, Rational design of alkali-resistant NO reduction catalysts using a stable hexagonal V-doped MoO3 support for alkali trapping, ChemCatChem 10 (2018) 3999-4003.

[156] C. Li, Z.W. Huang, Y.X. Chen, X.N. Liu, J.X. Chen, W.Y. Qu, Z. Ma, X.F. Tang*, Optimizing selective catalytic reduction of NO with NH3 on Fe2O3/WO3 via redox-acid synergy, ChemCatChem 10 (2018) 3990-3994.

[155] Y.X. Chen, W.Y. Qu, C. Li, J.X. Chen, Z. Ma, X.F. Tang*, Ultra-low-temperature ozone abatement on α-MnO2(001) facets with down-shifted lowest unoccupied orbitals, Industrial & Engineering Chemistry Research 57 (2018) 12590-12594.

[154] J.X. Chen, J.Y. Gao, Y.X. Chen, X.N. Liu, C. Li, W.Y. Qu, Z. Ma, X.F. Tang*, Electronic-structure-dependent performance of single-site potassium catalysts for formaldehyde emission control, Industrial & Engineering Chemistry Research 57 (2018) 12352-12357.

[153] Z.D. Liu, K. Sun, M.Z. Wei, Z. Ma*, Phosphorus-doped cerium vanadate nanorods with enhanced photocatalytic activity, Journal of Colloid and Interface Science 531 (2018) 618-627.

[152] J.L. Zhang, Z. Ma*, Ag3VO4/BiOIO3 heterojunction with enhanced visible-light-driven catalytic activity, Journal of the Taiwan Institute of Chemical Engineers 88 (2018) 177-185.

[151] J.L. Zhang, Z. Ma*, Ag-Ag2CO3/Bi2MoO6 composites with enhanced visible-light-driven catalytic activity, Journal of the Taiwan Institute of Chemical Engineers 88 (2018) 121-129.

[150] T. Meng, N. Ren*, Z. Ma*, Effect of copper precursors on the catalytic performance of Cu-ZSM-5 catalysts in N2O decomposition, Chinese Journal of Chemical Engineering 28 (2018) 1051-1058.

[149] J.L. Zhang, Z. Ma*, Porous g-C3N4 with enhanced adsorption and visible-light photocatalytic performance for removing aqueous dyes and tetracycline hydrochloride, Chinese Journal of Chemical Engineering 26 (2018) 753-760.

[148] J.L. Zhang, Z. Ma*, Ag-Ag3VO4/AgIO3 composites with enhanced visible-light-driven catalytic activity, Journal of Colloid and Interface Science 524 (2018) 16-24.

[147] J.Y. Gao, Z.W. Huang, Y.X. Chen, J. Wang, X. Gu, Z. Ma, J.M. Chen, X.F. Tang*, Activating inert alkali metal ions by electron transfer from manganese oxide for formaldehyde abatement, Chemistry – A European Journal 24 (2018) 681-689.

[146] H. Liu, Z. Ma*, Rh2O3/monoclinic CePO4 composite catalysts for N2O decomposition and CO oxidation, Chinese Journal of Chemical Engineering 26 (2018) 109-115.

[145] J.L. Zhang, Z. Ma*, Ag3VO4/AgI composites for photocatalytic degradation of dyes and tetracycline hydrochloride under visible light, Materials Letters 216 (2018) 216-218.

[144] S.Q. Jiang, X.N. Ye*, R.Y. Wang, Y. Tao, Z. Ma, X. Yang, J.M. Chen*, Measurements of nonvolatile size distribution and its link to traffic soot in urban Shanghai, Science of the Total Environment 615 (2018) 452-461.

2017年（25篇）

[143] J.L. Zhang, Z. Ma*, AgI/β-Ag2MoO4 heterojunctions with enhanced visible-light-driven catalytic activity, Journal of the Taiwan Institute of Chemical Engineers 81 (2017) 225-231.

[142] H. Liu, Z. Ma*, Rh2O3/hexagonal CePO4 nanocatalysts for N2O decomposition, Frontiers of Chemical Science and Engineering 11 (2017) 586-593.

[141] Y.X. Chen, Z.W. Huang, Z. Ma, J.M. Chen, X.F. Tang*, Fabrication, characterization, and stability of supported single-atom catalysts, Catalysis Science & Technology 7 (2017) 4250-4258.

[140] Q.Y. Zhang, L.H. Huang, S.F. Kang, C.C. Yin, Z. Ma, L.F. Cui*, Y.G. Wang*, CuO/Cu2O nanowire arrays grafted by reduced graphene oxide: Synthesis, characterization, and application in photocatalytic reduction of CO2, RSC Advances 7 (2017) 43642-43647.

[139] Y.X. Chen, Z.W. Huang, X. Gu, Z. Ma, J.M. Chen, X.F. Tang*, Top-down synthesis strategies: Maximum noble-metal atom efficiency in catalytic materials, Chinese Journal of Catalysis 38 (2017) 1588-1596.

[138] J.L. Zhang, Z. Ma*, Enhanced visible-light photocatalytic performance of Ag3VO4/Bi2WO6 heterojunctions in removing aqueous dyes and tetracycline hydrochloride, Journal of the Taiwan Institute of Chemical Engineers 78 (2017) 212-218.

[137] Y.X. Chen, Z.C.X. Dong, Z.W. Huang, M.J. Zhou, J.Y. Gao, J.X. Chen, C. Li, Z. Ma, J.M. Chen, X.F. Tang*, Tuning electronic states of catalytic sites enhances SCR activity of hexagonal WO3 by Mo framework substitution, Catalysis Science & Technology 7 (2017) 2467-2473.

[136] Y.X. Chen, J.Y. Gao, Z.W. Huang, M.J. Zhou, J.X. Chen, C. Li, Z. Ma, J.M. Chen, X.F. Tang*, Sodium rivals silver as single-atom active centers for catalyzing abatement of formaldehyde, Environmental Science & Technology 51 (2017) 7084-7090.

[135] B.B. Tu, Q.Q. Pang, H.S. Xu, X.M. Li, Y.L. Wang, Z. Ma, L.H. Weng, Q.W. Li*, Reversible redox activity in multicomponent metal-organic frameworks constructed from trinuclear copper pyrazolate building blocks, Journal of the American Chemical Society 139 (2017) 7998-8007.

[134] Y.Y. Xie, X.N. Ye*, Z. Ma, Y. Tao, R.Y. Wang, C. Zhang, X. Yang, J.M. Chen*, H. Chen, Insight into winter haze formation mechanisms based on aerosol hygroscopicity and effective density measurements, Atmospheric Chemistry and Physics 17 (2017) 7277-7290.

[133] W.Y. Qu, Y.X. Chen, Z.W. Huang, J.Y. Gao, M.J. Zhou, J.X. Chen, C. Li, Z. Ma, J.M. Chen, X.F. Tang*, Active tetrahedral iron sites of γ-Fe2O3 catalyzing NO reduction by NH3, Environmental Science & Technology Letters 4 (2017) 246-250.

[132] S. Liu, H.B. Zhou, Q.Y. Song, Z. Ma*, Synthesis of higher alcohols from CO2 hydrogenation over Mo-Co-K sulfide-based catalysts, Journal of the Taiwan Institute of Chemical Engineers 76 (2017) 18-26.

[131] J.L. Zhang, Z. Ma*, Flower-like Ag3VO4/BiOBr n-p heterojunction photocatalysts with enhanced visible-light-driven catalytic activity, Molecular Catalysis 436 (2017) 190-198.

[130] C.L. Li, Y.J. Hu, F. Zhang, J.M. Chen*, Z. Ma, X.N. Ye, X. Yang, L. Wang, X.F. Tang, R.H. Zhang, M. Mu, G.H. Wang, H.D. Kan, X.M. Wang, A. Mellouki, Multi-pollutants emissions from the burning of major agricultural residues in China and the related health-economic effects, Atmospheric Chemistry and Physics 17 (2017) 4957-4988.

[129] T. Meng, D.S. Mao*, Q.S. Guo, Z. Ma*, Effect of the Si/Al ratios of nanocrystalline HZSM-5 zeolite on the performance in catalytic conversion of ethanol to propylene, Journal of Nanoscience and Nanotechnology 17 (2017) 3779-3785.

[128] Y.F. Dai, S.D. Shen*, Z. Ma*, L.M. Ma, Z.S. Sun, J. Yu, C.Y. Wan, S. Han, D.S. Mao, G.Z. Lu*, High-surface-area mesoporous crystalline TiO2: Synthesis, characterization, and application as support for making stable Au catalysts, Journal of Nanoscience and Nanotechnology 17 (2017) 3772-3778.

[127] G.M. Yang, H.B. Yu, J.F. Zhang, H.F. Yin, Z. Ma*, S.H. Zhou*, AuPd@mesoporous SiO2: Synthesis and selectivity in catalytic hydrogenation/hydrodechlorination of p-chloronitrobenzene, Journal of Nanoscience and Nanotechnology 17 (2017) 3744-3750.

[126] B. Zhou, T. Meng, Y. Ren, T. Fan, Z. Ma*, Catalytic reduction of N2O by CO over mesoporous transition metal oxides, Journal of Nanoscience and Nanotechnology 17 (2017) 3709-3718.

[125] J.L. Zhang, Z. Ma*, Ag6Mo10O33/g-C3N4 1D-2D hybridized heterojunction as an efficient visible-light-driven photocatalyst, Molecular Catalysis 432 (2017) 285-291.

[124] Y.X. Chen, Z.W. Huang, M.J. Zhou, Z. Ma, J.M. Chen, X.F. Tang*, Single silver adatoms on nanostructured manganese oxide surfaces: Boosting oxygen activation for benzene abatement, Environmental Science & Technology 51 (2017) 2304-2311.

[123] H. Liu, Z. Ma*, Effect of different LaPO4 supports on the catalytic performance of Rh2O3/LaPO4 in N2O decomposition and CO oxidation, Journal of the Taiwan Institute of Chemical Engineers 71 (2017) 373-380.

[122] J.L. Zhang, Z. Ma*, Flower-like Ag2MoO4/Bi2MoO6 heterojunctions with enhanced photocatalytic activity under visible light irradiation, Journal of the Taiwan Institute of Chemical Engineers 71 (2017) 156-164.

[121] C.Y. Huang, Z. Ma*, C.X. Miao*, Y.H. Yue, W.M. Hua*, Z. Gao, Catalytic decomposition of N2O over Rh/Zn-Al2O3 catalysts, RSC Advances 7 (2017) 4243-4252.

[120] J.L. Zhang, Z. Ma*, Novel β-Ag2MoO4/g-C3N4 heterojunction catalysts with highly enhanced visible-light-driven photocatalytic activity, RSC Advances 7 (2017) 2163-2171.

[119] J.X. Chen, Y.X. Chen, M.J. Zhou, Z.W. Huang, J.Y. Gao, Z. Ma, J.M. Chen, X.F. Tang*, Enhanced performance of ceria-based NOx reduction catalysts by optimal support effect, Environmental Science & Technology 51 (2017) 473-478.

2016年（11篇）

[118] 林毅, 馬臻*, PdOx/金屬磷酸鹽催化劑催化分解N2O, 復旦學報(自然科學版) 55 (2016) 737-743.

[117] L. Zheng, M.J. Zhou, Z.W. Huang, Y.X. Chen, J.Y. Gao, Z. Ma, J.M. Chen, X.F. Tang*, Self-protection mechanism of hexagonal WO3-based de-NOx catalysts against alkali poisoning, Environmental Science & Technology 50 (2016) 11951-11956.

[116] Y. Tao, X.N. Ye*, Z. Ma, Y.Y. Xie, R.Y. Wang, J.M. Chen*, X. Yang, S.Q. Jiang, Insights into different nitrate formation mechanisms from seasonal variations of secondary inorganic aerosols in Shanghai, Atmospheric Environment 145 (2016) 1-9.

[115] J.L. Zhang, H. Liu, Z. Ma*, Flower-like Ag2O/Bi2MoO6 p-n heterojunction with enhanced photocatalytic activity under visible light irradiation, Journal of Molecular Catalysis A: Chemical 424 (2016) 37-44.

[114] Y.W. Cui, H. Liu, Y. Lin, Z. Ma*, Metal phosphate-supported RuOx catalysts for N2O decomposition, Journal of the Taiwan Institute of Chemical Engineers 67 (2016) 254-262.

[113] C.L. Li, Y.J. Hu, J.M. Chen*, Z. Ma, X.N. Ye, X. Yang, L. Wang, X.M. Wang, A. Mellouki, Physicochemical properties of carbonaceous aerosol from agricultural residue burning: Density, volatility, and hygroscopicity, Atmospheric Environment 140 (2016) 94-105.

[112] T. Meng, P.F. Xie, H.F. Qin, H. Liu, W.M. Hua, X. Li*, Z. Ma*, Fe2O3/SiO2 nanowires formed by hydrothermally transforming SiO2 spheres in the presence of Fe3+: Synthesis, characterization, and catalytic properties, Journal of Molecular Catalysis A: Chemical 421 (2016) 109-116.

[111] C.Y. Huang, Y.X. Jiang, Z. Ma*, P.F. Xie, Y. Lin, T. Meng, C.X. Miao*, Y.H. Yue, W.M. Hua*, Z. Gao, Correlation among preparation methods/conditions, physicochemical properties, and catalytic performance of Rh/hydroxyapatite catalysts in N2O decomposition, Journal of Molecular Catalysis A: Chemical 420 (2016) 73-81.

[110] H. Liu, Y. Lin, Z. Ma*, Au/LaPO4 nanowires: Synthesis, characterization, and catalytic CO oxidation, Journal of the Taiwan Institute of Chemical Engineers 62 (2016) 277-284.

[109] Z. Zheng*, J.Q. Gao, Z. Ma, Z.F. Wang, X.Y. Yang, Z.F. Wang, T. Jacquet, G.T. Fu, Urban flooding in China: Main causes and policy recommendations, Hydrological Processes 30 (2016) 1149-1152.

[108] H. Liu, Y. Lin, Z. Ma*, Rh2O3/mesoporous MOx-Al2O3 (M = Mn, Fe, Co, Ni, Cu, Ba) catalysts: Synthesis, characterization, and catalytic applications, Chinese Journal of Catalysis 37 (2016) 73-82.

2015年（14篇）

[107] C.L. Li, Z. Ma, J.M. Chen*, X.M. Wang, X.N. Ye, L. Wang, X. Yang, H.D. Kan, D.J. Donaldson*, A. Mellouki, Evolution of biomass burning smoke particles in the dark, Atmospheric Environment 120 (2015) 244-252.

[106] P.F. Xie, Z. Ma*, T. Meng, C.Y. Huang, C.X. Miao*, Y.H. Yue, W.M. Hua*, Z. Gao, Active Fe species of Fe2O3/Fe-Silicalite-1 nanowires in N2O decomposition, Journal of Molecular Catalysis A: Chemical 409 (2015) 50-58.

[105] T. Meng, Y. Lin, Z. Ma*, Effect of the crystal size of Cu-ZSM-5 on the catalytic performance in N2O decomposition, Materials Chemistry and Physics 163 (2015) 293-300.

[104] P.F. Xie, Y.J. Luo, Z. Ma*, C.Y. Huang, C.X. Miao*, W.M. Hua*, Y.H. Yue, Z. Gao, Catalytic decomposition of N2O over Fe-ZSM-11 catalysts prepared by different methods: Nature of active Fe species, Journal of Catalysis 330 (2015) 311-322.

[103] Y. Wang, H. Liu, P.P. Hu, Z.W. Huang, J.Y. Gao, F. Xu, Z. Ma*, X.F. Tang*, Enhancing the catalytic activity of Hollandite manganese oxide by supporting sub-10 nm ceria particles, Catalysis Letters 145 (2015) 1880-1884.

[102] T. Meng, N. Ren*, Z. Ma*, Silicalite-1@Cu-ZSM-5 core-shell catalysts for N2O decomposition, Journal of Molecular Catalysis A: Chemical 404 (2015) 233-239.

[101] H.M. Qin, X.S. Qian, T. Meng, Y. Lin, Z. Ma*, Pt/MOx/SiO2, Pt/MOx/TiO2, and Pt/MOx/Al2O3 catalysts for CO oxidation, Catalysts 5 (2015) 606-633.

[100] S.S. Sun, D.S. Mao*, J. Yu, Z.Q. Yang, G.Z. Lu, Z. Ma, Low-temperature CO oxidation on CuO/CeO2 catalysts: The significant effect of copper precursor and calcination temperature, Catalysis Science & Technology 5 (2015) 3166-3181.

[99] Y. Lin, T. Meng, Z. Ma*, Catalytic decomposition of N2O over RhOx supported on metal phosphates, Journal of Industrial and Engineering Chemistry 28 (2015) 138-146.

[98] C.Y. Huang, Z. Ma*, P.F. Xie, Y.H. Yue, W.M. Hua*, Z. Gao, Hydroxyapatite-supported rhodium catalysts for N2O decomposition, Journal of Molecular Catalysis A: Chemical 400 (2015) 90-94.

[97] P.F. Xie, Y.J. Luo, Z. Ma*, L.Y. Wang, C.Y. Huang, Y.H. Yue, W.M. Hua*, Z. Gao, CoZSM-11 catalysts for N2O decomposition: Effect of preparation methods and nature of active sites, Applied Catalysis B: Environmental 170 (2015) 34-42.

[96] X.J. Zhang, P.P. Zhang, H.B. Yu, Z. Ma*, S.H. Zhou*, Mesoporous KIT-6 supported Pd-MxOy (M = Ni, Co, Fe) catalysts with enhanced selectivity for p-chloronitrobenzene hydrogenation, Catalysis Letters 145 (2015) 784-793.

[95] H. Liu, K. Tao, H.B. Yu, C. Zhou, Z. Ma*, D.S. Mao*, S.H. Zhou*, Effect of pretreatment gases on the performance of WO3/SiO2 catalysts in the metathesis of 1-butene and ethene to propene, Comptes Rendus Chimie 18 (2015) 644-653.

[94] Z. Ma*, F. Tao*, X.L. Gu, Development of new gold catalysts for removing CO from H2, in: Heterogeneous Catalysis at Nanoscale for Energy Applications, F. Tao, W.A. Schneider, P.V. Kamat (eds.), Wiley-Blackwell, New York (2015) 217-238.

2014年（14篇）

[93] X.S. Qian, H.M. Qin, T. Meng, Y. Lin, Z. Ma*, Metal phosphate-supported Pt catalysts for CO oxidation, Materials 7 (2014) 8105-8130.

[92] Q.Y. Zhang, B. Li, Z. Ma, Y.G. Wang*, X. Li*, One-step nanocasting synthesis of mesostructured magnetic Fe/γ-Fe2O3/graphitic carbon composites, Journal of Alloys and Compounds 617 (2014) 713-715.

[91] P.F. Xie, L.F. Chen, Z. Ma*, C.Y. Huang, Y.H. Yue, W.M. Hua*, Y. Tang*, Z. Gao, Hydrothermal conversion of Fe2O3/SiO2 spheres into Fe2O3/Silicalite-1 nanowires, Microporous and Mesoporous Materials 200 (2014) 52-60.

[90] W. Zou, P.F. Xie, W.M. Hua, Y.D. Wang, D.J. Kong, Y.H. Yue*, Z. Ma*, W.M. Yang, Z. Gao, Catalytic decomposition of N2O over Cu-ZSM-5 nanosheets, Journal of Molecular Catalysis A: Chemical 394 (2014) 83-88.

[89] Y. Tao, X.N. Ye*, Z. Ying, Z. Ma, J.M. Chen*, Size distribution of water-soluble inorganic ions in urban aerosols in Shanghai, Atmospheric Pollution Research 5 (2014) 639-647.

[88] Y. Ren*, Z. Ma*, S. Dai, Nanosize control on porous β-MnO2 and their catalytic activity in CO oxidation and N2O decomposition, Materials 7 (2014) 3547-3556.

[87] C. Lin, K. Tao, D.Y. Hua, Z. Ma*, S.H. Zhou*, Transformation of Au3M/SiO2 (M = Ni, Co, Fe) into Au-MOx/SiO2 catalysts for the reduction of p-nitrophenol, Catalysis Letters 144 (2014) 1001-1008.

[86] P.F. Xie, Z. Ma*, H.B. Zhou, C.Y. Huang, Y.H. Yue, W. Shen, H.L. Xu, W.M. Hua*, Z. Gao, Catalytic decomposition of N2O over Cu-ZSM-11 catalysts, Microporous and Mesoporous Materials 191 (2014) 112-117.

[85] Z. Ma*, Cobalt oxide catalysts for environmental remediation, Current Catalysis 3 (2014) 15-26.

[84] L.P. Qian*, Z. Ma, Y. Ren, H.C. Shi, B. Yue, S.J. Feng, J.Z. Shen, S.H. Xie, Investigation of La promotion mechanism on Ni/SBA-15 catalysts in CH4 reforming with CO2, Fuel 122 (2014) 47-53.

[83] Z. Ma*, S. Dai, Stabilizing gold nanoparticles by solid supports, in: Heterogeneous Gold Catalysts and Catalysis, Z. Ma, S. Dai (eds.), Royal Society of Chemistry, Cambridge (2014) 1-26.

[82] Z. Ma*, F. Tao*, Metal salt-based gold nanocatalysts, in: Metal Nanoparticles for Catalysis: Advances and Applications, F. Tao (ed.), Royal Society of Chemistry, Cambridge (2014) 157-171.

[81] Z. Ma*, F. Zaera, Heterogeneous catalysis by metals, in: Encyclopedia of Inorganic and Bioinorganic Chemistry, R.A. Scott (ed.), John Wiley & Sons, Chichester (2014) eibc0079 (16 pp).

[80] Z. Ma, F. Zaera*, 催化劑表面的手性修飾, 非均相催化劑設計, U.S. Ozkan編, 中國石化催化劑有限公司譯, 中國石化出版社, 北京 (2014) 115-143.

2013年（8篇）

[79] H. Liu, C. Lin, Z. Ma*, H.B. Yu*, S.H. Zhou, Gold nanoparticles on mesoporous SiO2-coated magnetic Fe3O4 spheres: A magnetically separatable catalyst with good thermal stability, Molecules 18 (2013) 14258-14267.

[78] C. Lin, K. Tao, D.Y. Hua*, Z. Ma*, S.H. Zhou*, Size effect of gold nanoparticles in catalytic reduction of p-nitrophenol with NaBH4, Molecules 18 (2013) 12609-12620.

[77] J.L. Wang, H.B. Yu, Z. Ma*, S.H. Zhou*, Enhanced stability of CaO and/or La2O3 promoted Pd/Al2O3 egg-shell catalysts in partial oxidation of methane to syngas, Molecules 18 (2013) 8289-8297.

[76] F. Tao*, Z. Ma*, Water-gas shift on gold catalysts: Catalyst systems and fundamental insights, Physical Chemistry Chemical Physics 15 (2013) 15260-15270.

[75] Y. Ren, Z. Ma, R.E. Morris, Z. Liu, F. Jiao, S. Dai, P.G. Bruce*, A solid with a hierarchical tetramodal micro-meso-macro pore size distribution, Nature Communications 4 (2013) 2015 (7 pp).

[74] Z. Ma*, Y. Ren*, Y.B. Lu, P.G. Bruce, Catalytic decomposition of N2O on ordered crystalline metal oxides, Journal of Nanoscience and Nanotechnology 13 (2013) 5093-5103.

[73] Z. Ma*, B. Zhou, Y. Ren*, Crystalline mesoporous transition metal oxides: Hard-templating synthesis and application in environmental catalysis, Frontiers of Environmental Science & Engineering 7 (2013) 341-355.

[72] X.N. Ye*, C. Tang, Z. Ying, J.M. Chen*, Z. Ma, L.D. Kong, X. Yang, W. Gao, F.H. Geng, Hygroscopic growth of urban aerosol particles during the 2009 Mirage-Shanghai Campaign, Atmospheric Environment 64 (2013) 263-269.

2012年（5篇）

[71] 操婧婷, 周海東*, 黃誌偉, 馬臻*, 唐幸福*, 鐵錳氧化物對NH3低溫選擇性還原NO的催化活性, 復旦學報(自然科學版) 51 (2012) 632-636 & 643.

[70] Y. Ren*, Z. Ma*, P.G. Bruce, Ordered mesoporous NiCoMnO4: Synthesis and application in energy storage and catalytic decomposition of N2O, Journal of Materials Chemistry 22 (2012) 15121-15127.

[69] Y. Ren, Z. Ma*, P.G. Bruce*, Ordered mesoporous metal oxides: Synthesis and applications, Chemical Society Reviews 41 (2012) 4909-4927.

[68] Z. Ma*, Y. Ren*, P.G. Bruce, Co3O4-KIT-6 composite catalysts: Synthesis, characterization, and application in catalytic decomposition of N2O, Journal of Nanoparticle Research 14 (2012) 874 (11pp).

[67] Y. Ren*, Z. Ma*, P.G. Bruce, Transformation of mesoporous Cu/Cu2O into porous Cu2O nanowires in ethanol, CrystEngComm 14 (2012) 2617-2620.

2011年（8篇）

[66] Y. Ren*, Z. Ma, P.G. Bruce, Ordered mesoporous NiMn2Ox with hematite or spinel structure: Synthesis and application in electrochemical energy storage and catalytic conversion of N2O, CrystEngComm 13 (2011) 6955-6959.

[65] X.N. Ye*, Z. Ma, J.C. Zhang, H.H. Du, J.M. Chen*, H. Chen, X. Yang, W. Gao, F.H. Geng, Important role of ammonia on haze formation in Shanghai, Environmental Research Letters 6 (2011) 024019 (5 pp).

[64] Z. Ma*, S. Dai*, Design of novel structured gold nanocatalysts, ACS Catalysis 1 (2011) 805-818.

[63] Y. Ren, P.G. Bruce*, Z. Ma*, Solid-solid conversion of ordered crystalline mesoporous metal oxides under reducing atmosphere, Journal of Materials Chemistry 21 (2011) 9312-9318.

[62] R. Mayes, P. Fulvio, Z. Ma, S. Dai*, Phosphorylated mesoporous carbon as a solid-acid catalyst, Physical Chemistry Chemical Physics 13 (2011) 2492-2494.

[61] H.F. Yin, Z. Ma, M.F. Chi, S. Dai*, Heterostructured catalysts prepared by dispersing Au@Fe2O3 core-shell structures on supports and their performance in CO oxidation, Catalysis Today 160 (2011) 87-95.

[60] Z. Ma*, S. Dai*, Development of novel supported gold catalysts: A materials perspective, Nano Research 4 (2011) 3-32.

[59] X.N. Ye*, Z. Ma, D.W. Hu, X. Yang, J.M. Chen*, Size-resolved hygroscopicity of submicrometer urban aerosols in Shanghai during wintertime, Atmospheric Research 99 (2011) 353-364.

2010年（8篇）

[58] H.F. Yin, Z. Ma*, H.G. Zhu, M.F. Chi, S. Dai*, Evidence for and mitigation of the encapsulation of gold nanoparticles within SiO2 matrix upon calcining Au/SiO2 catalysts at high temperatures: Implication to catalyst deactivation, Applied Catalysis A: General 386 (2010) 147-156.

[57] J. Zhang, D.S. Zhao*, Z. Ma, Y.N. Wang, Phase-boundary photocatalytic oxidation of dibenzothiophene over amphiphic Ti-MCM-41 molecular sieve, Catalysis Letters 138 (2010) 111-115.

[56] Z. Ma*, H.F. Yin, S. Dai*, Influence of preparation methods on the performance of metal phosphate-supported gold catalysts in CO oxidation, Catalysis Letters 138 (2010) 40-45.

[55] E.W. Hagaman*, J. Jiao, B.H. Chen, Z. Ma, H.F. Yin, S. Dai, Surface alumina species on modified titanium oxide: A solid-state 27Al MAS and 3QMAS NMR investigation of catalyst supports, Solid State Nuclear Magnetic Resonance 37 (2010) 82-90.

[54] H.F. Yin, Z. Ma, M.F. Chi, S. Dai*, Activation of dodecanethiol-capped gold catalysts for CO oxidation by treatment with KMnO4 or K2MnO4, Catalysis Letters 136 (2010) 209-221.

[53] Z. Ma, H.F. Yin, S. Dai*, Performance of Au/MxOy/TiO2 catalysts in water-gas shift reaction, Catalysis Letters 136 (2010) 83-91.

[52] J.N. Zhang, Z. Ma*, J. Jiao, H.F. Yin, W.F. Yan, E.W. Hagaman, J.H. Yu, S. Dai*, Surface functionalization of mesoporous silica SBA-15 by liquid-phase grafting of zirconium phosphate, Microporous and Mesoporous Materials 129 (2010) 200-209.

[51] Z. Ma, J.H. Yu, S. Dai*, Preparation of inorganic materials using ionic liquids, Advanced Materials 22 (2010) 261-285.

2009年（9篇）

[50] J.N. Zhang, Z. Ma, J. Jiao, H.F. Yin, W.F. Yan, E.W. Hagaman, J.H. Yu*, S. Dai*, Layer-by-layer grafting of titanium phosphate onto mesoporous silica SBA-15 surfaces: Synthesis, characterization, and applications, Langmuir 25 (2009) 12541-12549.

[49] J.F. Lai, Z. Ma, L. Mink, L.J. Mueller, F. Zaera*, Influence of peripheral groups on the physical and chemical behavior of cinchona alkaloids, Journal Physical Chemistry B 113 (2009) 11696-11701.

[48] M.J. Li, Z.L. Wu, Z. Ma, V. Schwartz, D.R. Mullins, S. Dai, S.H. Overbury*, CO oxidation on Au/FePO4 catalyst: Reaction pathways and nature of Au sites, Journal of Catalysis 266 (2009) 98-105.

[47] Y. Ren, Z. Ma, L.P. Qian, S. Dai, H.Y. He, P.G. Bruce*, Ordered crystalline mesoporous oxides as catalysts for CO oxidation, Catalysis Letters 131 (2009) 146-154.

[46] S.H. Zhou, Z. Ma, G.A. Baker, A.J. Rodinone, Q. Zhu, H.M. Luo, Z.L. Wu, S. Dai*, Self-assembly of metal-oxide nanoparticles into hierarchically patterned porous architectures using ionic liquid/oil emulsions, Langmuir 25 (2009) 7229-7233.

[45] B. Lee*, Z. Ma, Z.T. Zhang, C. Park, S. Dai*, Influences of synthesis conditions and mesoporous structures on the gold nanoparticles supported on mesoporous silica hosts, Microporous and Mesoporous Materials 122 (2009) 160-167.

[44] S.H. Zhou, Z. Ma, H.F. Yin, Z.L. Wu, B. Eichhorn, S.H. Overbury, S. Dai*, Low-temperature solution-phase synthesis of NiAu alloy nanoparticles via butyllithium reduction: Influences of synthesis details and application as the precursor to active Au-NiO/SiO2 catalysts through proper pretreatment, Journal of Physical Chemistry C 113 (2009) 5758-5765.

[43] Z. Ma, F. Zaera*, Chiral modification of catalytic surfaces, in: Design of Heterogeneous Catalysts: New Approaches based on Synthesis, Characterization and Modelling, U.S. Ozkan (ed.), Wiley-VCH, Weinheim (2009) 113-140.

[42] Z. Ma, S.H. Overbury, S. Dai*, Gold nanoparticles as chemical catalysts, in: Nanomaterials: Inorganic and Bioinorganic Perspectives, C.M. Lukehart, R.A. Scott (eds.), John Wiley & Sons, Chichester (2009) 247-266.

2008年（10篇）

[41] Z. Ma*, Reflections on applied catalysis and fundamental model studies, in: Heterogeneous Catalysis Research Progress, M.B. Gunther (ed.), Nova Science Publishers, New York (2008) 235-266.

[40] Z. Ma, H.F. Yin, S.H. Overbury, S. Dai*, Metal phosphates as a new class of supports for gold nanocatalysts, Catalysis Letters 126 (2008) 20-30.

[39] I. Lee, Z. Ma, S. Kaneko, F. Zaera*, 1-(1-Naphthyl)ethylamine adsorption on platinum surfaces: On the mechanism of chiral modification in catalysis, Journal of the American Chemical Society 130 (2008) 14597-14604.

[38] Z. Ma, S. Dai*, Materials design of advanced performance metal catalysts, Materials Technology 23 (2008) 81-87.

[37] D.H. Wang, Z. Ma, S. Dai, J. Liu*, Z.M. Nie, M.H. Engelhard, Q.S. Huo, C.M. Wang, R. Kou, Low-temperature synthesis of tunable mesoporous crystalline transition metal oxides and applications as Au catalyst supports, Journal of Physical Chemistry C 112 (2008) 13499-13509.

[36] Z. Ma, S. Brown, J.Y. Howe, S.H. Overbury, S. Dai*, Surface modification of Au/TiO2 catalysts by SiO2 via atomic layer deposition, Journal of Physical Chemistry C 112 (2008) 9448-9457.

[35] H.F. Yin, Z. Ma, S.H. Overbury, S. Dai*, Promotion of Au(en)2Cl3-derived Au/fumed SiO2 by treatment with KMnO4, Journal of Physical Chemistry C 112 (2008) 8349-8358.

[34] L. Mink, Z. Ma, R.A. Olsen, J.N. James, D.S. Sholl, L.J. Mueller, F. Zaera*, The physico-chemical properties of cinchona alkaloids responsible for their unique performance in chemical catalysis, Topics in Catalysis 48 (2008) 120-127.

[33] Z. Ma, H.G. Zhu, W.F. Yan, S.H. Overbury, S. Dai*, Functionalized mesoporous materials for gold catalysis, in: Nanoporous Materials: Proceedings of the 5th International Symposium, A. Sayari, M. Jaroniec (eds.), World Scientific Publishing, Singapore (2008) 529-542.

[32] W.F. Yan, Z. Ma, S.M. Mahurin, J. Jiao, E.W. Hagaman, S.H. Overbury, S. Dai*, Novel Au/TiO2/Al2O3·xH2O catalysts for CO oxidation, Catalysis Letters 121 (2008) 209-218.

2007年（6篇）

[31] Z. Ma, I. Lee, F. Zaera*, Factors controlling adsorption equilibria from solution onto solid surfaces: The uptake of cinchona alkaloids on platinum surfaces, Journal of the American Chemical Society 129 (2007) 16083-16090.

[30] Z. Ma, C.D. Liang, S.H. Overbury, S. Dai*, Gold nanoparticles on electroless-deposition-derived MnOx/C: Synthesis, characterization, and catalytic CO oxidation, Journal of Catalysis 252 (2007) 119-126.

[29] H.G. Zhu, Z. Ma, S.H. Overbury, S. Dai*, Rational design of gold catalysts with enhanced thermal stability: Post modification of Au/TiO2 by amorphous SiO2 decoration, Catalysis Letters 116 (2007) 128-135.

[28] Z. Ma, S. Brown, S.H. Overbury, S. Dai*, Au/PO43-/TiO2 and PO43-/Au/TiO2 catalysts for CO oxidation: Effect of synthesis details on catalytic performance, Applied Catalysis A: General 327 (2007) 226-237.

[27] Z. Ma, S.H. Overbury, S. Dai*, Au/MxOy/TiO2 catalysts for CO oxidation: Promotional effect of main-group, transition, and rare-earth metal oxide additives, Journal of Molecular Catalysis A: Chemical 273 (2007) 186-197.

[26] H.G. Zhu, Z. Ma, J.C. Clark, Z.W. Pan, S.H. Overbury, S. Dai*, Low-temperature CO oxidation on Au/fumed SiO2-based catalysts prepared from Au(en)2Cl3 precursor, Applied Catalysis A: General 326 (2007) 89-99.

2006年（4篇）

[25] Z. Ma, F. Zaera*, Competitive chemisorption between pairs of cinchona alkaloids and related compounds from solution onto platinum surfaces, Journal of the American Chemical Society 128 (2006) 16414-16415.

[24] Z. Ma*, Solvent effect on CO oxidation as a novel diagnosing tool to pin down low-coverage CO at the liquid-solid interface: An in situ infrared study, Journal of Colloid and Interface Science 304 (2006) 419-430.

[23] Z. Ma, F. Zaera*, Organic chemistry on solid surfaces, Surface Science Reports 61 (2006) 229-281.

[22] Z. Ma, F. Zaera*, Characterization of heterogeneous catalysts, in: Surface and Nanomolecular Catalysis, R.M. Richards (ed.), Taylor & Francis (CRC Press), Boca Raton (2006) 1-37.

2005年（2篇）

[21] Z. Ma, F. Zaera*, Heterogeneous catalysis by metals, in: Encyclopedia of Inorganic Chemistry (Second Edition), R.B. King (ed.), John Wiley & Sons, Chichester (2005) 1768-1784.

[20] Z. Ma, F. Zaera*, Role of the solvent in the adsorption-desorption equilibrium of cinchona alkaloids between solution and a platinum surface: Correlations among solvent polarity, cinchona solubility, and catalytic performance, Journal of Physical Chemistry B 109 (2005) 406-414.

2004年（2篇）

[19] Z. Ma, F. Zaera*, In situ reflection-absorption infrared spectroscopy at the solid-liquid interface: Decomposition of organic molecules on polycrystalline platinum substrates, Catalysis Letters 96 (2004) 5-12.

[18] Z. Ma, I. Lee, J. Kubota, F. Zaera*, In situ characterization of the adsorption of cinchona chiral modifiers on platinum surfaces, Journal of Molecular Catalysis A: Chemical 216 (2004) 199-207.

2003年（3篇）

[17] Z. Ma, J. Kubota, F. Zaera*, The influence of dissolved gases on the adsorption of cinchonidine from solution onto Pt surfaces: An in situ infrared study, Journal of Catalysis 219 (2003) 404-416.

[16] J. Kubota, Z. Ma, F. Zaera*, In-situ characterization of adsorbates in solid-liquid interfaces by reflection-absorption infrared spectroscopy, Langmuir 19 (2003) 3371-3376.

[15] 馬臻, 陶泳, 高滋*, 氟裏昂水解的催化劑體系, 化學世界 44 (2003) 157-160.

2002年（2篇）

[14] N. Ma, Z. Ma, Y.H. Yue, Z. Gao*, Reaction testing of phenol hydroxylation and cyclohexane oxidation by gas chromatography: Influence of residual hydrogen peroxide, Journal of Molecular Catalysis A: Chemical 184 (2002) 361-370.

[13] Z. Ma, Y.H. Yue, X.Y. Deng, Z. Gao*, Nanosized anatase TiO2 as precursor for preparation of sulfated titania catalysts, Journal of Molecular Catalysis A: Chemical 178 (2002) 97-104.

2001年（2篇）

[12] X.Y. Deng, Z. Ma, Y.H. Yue, Z. Gao*, Catalytic hydrolysis of dichlorodifluoromethane over nanosized titania-supported titanyl sulfate, Journal of Catalysis 204 (2001) 200-208.

[11] 馬臻, 華偉明, 高滋*, 氟裏昂催化分解研究進展, 化學通報 (2001) 339-344.

2000年（9篇）

[10] 樂英紅, 馬臻, 華偉明, 高滋*, 二氧化鈦介孔分子篩的合成和表征, 化學學報 58 (2000) 777-780.

[9] 馬臻, 華偉明, 唐頤, 高滋*, 用以分解氟裏昂-12的新型催化劑WO3/Al2O3, 應用化學 17 (2000) 319-321.

[8] Z. Ma, W.M. Hua, Y. Tang, Z. Gao*, Catalytic hydrolysis of CFC-12 over solid acid Ti(SO4)2, Chinese Chemical Letters 11 (2000) 311-314.

[7] Z. Ma, W.M. Hua, Y. Tang, Z. Gao*, A novel CFC-12 hydrolysis catalyst: WO3/SnO2, Chinese Chemical Letters 11 (2000) 87-88.

[6] W.M. Hua, F. Zhang, Z. Ma, Y. Tang, Z. Gao*, WO3/ZrO2 solid acid as a catalyst for the decomposition of chlorofluorocarbon (CFC-12), Chemical Research in Chinese Universities 16 (2000) 185-187.

[5] Z. Ma, W.M. Hua, Y. Tang, Z. Gao*, Catalytic decomposition of CFC-12 on solid acids SO42-/MxOy (M = Zr, Ti, Sn, Fe, Al), Chinese Journal of Chemistry 18 (2000) 341-345.

[4] Z. Ma, W.M. Hua, Y. Tang, Z. Gao*, Catalytic decomposition of CFC-12 over solid acids WO3/MxOy (M = Ti, Sn, Fe), Journal of Molecular Catalysis A: Chemical 159 (2000) 335-345.

[3] W.M. Hua, F. Zhang, Z. Ma, Y. Tang, Z. Gao*, Catalytic hydrolysis of CFC-12 over WO3/ZrO2, Catalysis Letters 65 (2000) 85-89.

[2] Z. Ma, W.M. Hua, Y. Tang, Z. Gao*, Catalytic decomposition of CFC-12 over heteropolyacids, 催化學報 21 (2000) 3-4.

1999年（1篇）

[1] Z. Ma, W.M. Hua, Y. Tang, Z. Gao*, Catalytic decomposition of CFC-12 over WO3/TiO2, Chemistry Letters (1999) 1215-1216.