{"id":10,"date":"2017-01-05T12:22:16","date_gmt":"2017-01-05T17:22:16","guid":{"rendered":"https:\/\/cbe.ncsu.edu\/ligroup\/?page_id=10"},"modified":"2026-05-04T16:53:50","modified_gmt":"2026-05-04T20:53:50","slug":"publications","status":"publish","type":"page","link":"https:\/\/cbe.ncsu.edu\/ligroup\/publications\/","title":{"rendered":"Publications"},"content":{"rendered":"<h3><span style=\"color: #000000\">Journal Publications<\/span><\/h3>\n<p><span style=\"font-size: 18pt\"><strong>2026<\/strong><\/span><\/p>\n<ul>\n<li>SB Portillo, M Kosari, F Li. \u201cSupported Transition Metals for Catalytic Decomposition of Methane: Advances, Challenges, and Outlook\u201d <strong>2026.<\/strong> <em>ACS Catalysis. <\/em><\/li>\n<li>W Martin, S Iftikhar, T Aniekwensi, A Mathis, L Neal, F Li. \u201cChemical-Looping Reforming of Methane with Tunable CO<sub>2<\/sub> Utilization over Ruddlesden\u2013Popper and Perovskite Carriers\u201d. <strong>2026. <\/strong><em>Industrial &amp; Engineering Chemistry Research.<\/em><\/li>\n<li>S Iftikhar<sup>1<\/sup>, W Martin<sup>1<\/sup>, A Pedersen, SB Portillo, J Liu, and F Li. \u201cLaFe<sub>1-x<\/sub>MnxO<sub>3\u2212\u03b4<\/sub> as Effective Redox Catalysts for CO<sub>2<\/sub> Splitting and Methane Partial Oxidation in a Cyclic Redox Scheme\u201d. <strong>2026. <\/strong><em>Catalysis Today. <\/em><\/li>\n<li>D Chacko, L Neal, A Pedersen, F Li. \u201cUnveiling the Role of Oxygen Species in Surface Promoted Fe-Mn Oxides for Chemical Looping Oxidative Dehydrogenation of Ethane\u201d. <strong>2026. <\/strong><em>EES Catalysis. <\/em><\/li>\n<\/ul>\n<p><span style=\"font-size: 18pt\"><strong>2025<\/strong><\/span><\/p>\n<ul>\n<li>SB Portillo, Y Mei, M Kosari, E Nguyen, A Talpade, F Li. \u201cStrontium Iron Hexaaluminates for CO<sub>x<\/sub> free Hydrogen and Carbon Nanotubes via Catalytic Decomposition of Methane\u201d. <strong>2025. <\/strong><em>ACS Catalysis. <\/em><\/li>\n<li>K Yang and F Li. \u201cComputationally Accelerated Discovery of Mixed Metal Compounds for Chemical Looping Combustion and Beyond\u201d. <strong>2025. <\/strong><em>Energy and Environmental Science. <\/em><\/li>\n<li>S Razavi, M Kosari, F Li. \u201cAmine-modified mesoporous SiO<sub>2<\/sub> spheres (MSS-(x) APTMS) as a promising CO2 sorbent\u201d. <strong>2025. <\/strong><em>Journal of Physics: Energy. <\/em><\/li>\n<li>MC Garcia-Vallejo<sup>1<\/sup>, M Rukh<sup>1<\/sup>, S Wang, R Cai, L Brody, C Killmer, K Lan, Y Yao, F Li, S Park. \u201cA new approach to improve the economic and environmental attractiveness of biomethane from biomass gasification with redox-activated CO<sub>2<\/sub> sorbents\u201d <strong>2025. <\/strong><em>Chemical Engineering Journal.<\/em><\/li>\n<li>R Cai, KH Bektas, S Raza, J Massey, Y Tian, J Liu, F Li. \u201cRedox-Active Oxide\/Molten Salt Composites for Hybrid Thermal-Chemical Energy Storage.\u201d <strong>2025. <\/strong><em>Advanced Energy and Sustainability Research.<\/em><\/li>\n<li>M Kosari, C O\u2019Brien, K Yang, Y Mei, E Hondos, S Xi, L Neal, and F Li. \u201cBimodal Hierarchically Porous SiO<sub>2<\/sub> Sphere-Supported Catalysts for Dry Reforming of Methane.\u201d <strong>2025. <\/strong><em>ACS Catalysis. <\/em><\/li>\n<li>Y Yao, M Rukh, C Killmer, CP Smith, L Neal, F Li. \u201cSr<sub>2<\/sub>MnO<sub>4<\/sub> as a Reactive CO<sub>2<\/sub> Sorbent for Sorption-Enhanced Steam Reforming of Biogas to Green Hydrogen\u201d <strong>2025. <\/strong><em>Chemical Engineering Journal.<\/em><\/li>\n<li>M Rukh, R Cai, S Razavi, SB Portillo, Y Yao, L Neal, and F Li. \u201cRuddlesden-Popper structured Sr<sub>3<\/sub>Fe<sub>2<\/sub>O<sub>7-\u03b4<\/sub> as redox-activated CO<sub>2<\/sub> sorbents for green hydrogen production\u201d <strong>2025. <\/strong><em>Advanced Energy and Sustainability Research.<\/em><\/li>\n<li>JW Stallrich, R Singh, K Vogt-Lowell, F Li. \u201cPowerful Foldover Designs\u201d. <strong>2025. <\/strong><em>Quality and Reliability Engineering International.<\/em><\/li>\n<li>L Brody, M Bekheet, K Yang, JT M\u00fcller, SB Portillo, M Rukh, R Schom\u00e4cker, A Gili, A Gurlo, and F Li. \u201cReversible Phase Transitions Enable Cyclic Isothermal CO<sub>2<\/sub> Capture in Redox-Activated Perovskite-Structured Sorbents\u201d. <strong>2025. <\/strong><em>Advanced Functional Materials.<\/em><\/li>\n<li>KH Bektas, R Cai, S Raza, J Liu, F Li. \u201cRedox-Active Oxide Molten Salt Composites as a New Family of High-Capacity Thermal Energy Storage Materials\u201d. <strong>2025. <\/strong><em>Journal of Materials Chemistry A.<\/em><\/li>\n<li>SB Portillo, M Kosari, K Yang, A Pedersen, E Nguyen, A Talpade, F Li.\u00a0\u201cExsoluted Ni from Hexaaluminates for CO<sub>x<\/sub> Free Hydrogen and Carbon Nanotubes via the Catalytic Decomposition of Methane\u201d <strong>2025. <\/strong><em>ACS Catalysis. <\/em><\/li>\n<li>S Razavi, V Rahmanian, R Cai, M Rukh, SA Khan, F Li. \u201cPerovskite Oxides as A New Family of Tunable CO<sub>2<\/sub> Sorbents\u201d. <strong>2025<\/strong>. <em>Journal of Materials Chemistry A.<\/em><\/li>\n<li>D Chacko, L Neal, B Mosevitzky Lis, J Liu, A Pedersen, I Wachs, Fanxing Li. \u201cEffective CO<sub>x<\/sub> Suppression by a Na<sub>4<\/sub>Mg(WO<sub>4<\/sub>)<sub>3<\/sub> Promoter in Chemical Looping &#8211; Oxidative Dehydrogenation of Ethane\u201d. <strong>2025.<\/strong> <em>ACS Catalysis. <\/em><\/li>\n<li>M Kosari, SB Portillo, S Xi, A Pedersen, A Talpade, and F Li. &#8220;Zr-promoted Ni nanoparticles in mesoporous silica spheres (NiZr\/mSiO2) for catalytic decomposition of methane&#8221;. <strong>2025<\/strong>. <em>Chemical Engineering Journal<\/em>.<\/li>\n<li>D Chacko, LM Neal, BM Lis, J Liu, A Pedersen, IE Wachs, and and F Li. &#8220;Effective CO<sub><i>x<\/i><\/sub>\u00a0Suppression by a Na<sub>4<\/sub>Mg(WO<sub>4<\/sub>)<sub>3<\/sub>\u00a0Promoter in Chemical Looping Oxidative Dehydrogenation of Ethane&#8221;. <strong>2025<\/strong>. <em>ACS Catalysis<\/em>.<\/li>\n<li>S Razavi, V Rahmanian, R Cai, M Rukh, SA Khan, and F Li. &#8220;Perovskite Oxides as A New Family of Tunable CO2 Sorbents&#8221;. 2025. <em>Journal of Materials Chemistry A<\/em>.<\/li>\n<\/ul>\n<p><span style=\"font-size: 18pt\"><strong>2024<\/strong><\/span><\/p>\n<ul>\n<li>M Rukh<sup>1<\/sup>, R Cai<sup>1<\/sup>, L Brody, and F Li. &#8220;Isothermal CO2 separation Enabled by redox-active mixed oxide sorbents&#8221;. <strong>2024<\/strong>. <em>Chemical Engineering Journal<\/em>.<\/li>\n<li>R Wu, E Carrejo, MS Reza, E Woods, S Razavi, S Park, F Li, and WJ Sagues. &#8220;Kinetic assessment of pulp mill-derived lime mud calcination in high CO2 atmosphere&#8221;. <strong>2024<\/strong>. <em>Fuel<\/em>.<\/li>\n<li>A Frye, J Liu, L Neal, and F Li. &#8220;Sustainable Styrene Production through Chemical Looping Oxidative Dehydrogenation: An Experimentally Informed Technoeconomic Study&#8221;. <strong>2024<\/strong>. <em>ACS Sustainable Chemistry &amp; Engineering.<\/em><\/li>\n<li>L Brody, B. M. Lis, A. P. Ortiz, M Kosari, K Vogt-Lowell, S Portillo, R Schoma\u0308cker, I. E. Wachs, and F Li. &#8220;Synergistic Cooperation of Dual-Phase Redox Catalysts in Chemical Looping Oxidative Coupling of Methane&#8221;. <strong>2024<\/strong>. <em>ACS Catalysis<\/em>.<\/li>\n<li>D Song, Y Lin, S Fang, Y Li, K Zhao, X Chen, Z Huang, F He, Z Zhao, H Huang, and F Li. &#8220;Unraveling the atomic interdiffusion mechanism of NiFe<sub>2<\/sub>O<sub>4<\/sub>\u00a0oxygen carriers during chemical looping CO<sub>2<\/sub>\u00a0conversion&#8221;. <strong>2024<\/strong>. <em>Carbon Energy<\/em>.<\/li>\n<li>V Haribal, S Iftikhar, A Tong, A Rayer, C Sanderson, L Neal, and F Li. &#8220;Technoeconomic and Emissions Analysis of the Hybrid Redox Process for the Production of Acetic Acid with CO<sub>2<\/sub>\u00a0Utilization&#8221;. <strong>2024<\/strong>. <em>Advanced Sustainable Systems<\/em>.<\/li>\n<li>H Bektas, R Cai, L Brody, and F Li. &#8220;Structural and Thermodynamic Assessment of Ba and Ba\/Mg Substituted SrFeO3\u2212\u03b4 for \u201cLow-Temperature\u201d Chemical Looping Air Separation&#8221;.\u00a0<strong>2024<\/strong>.\u00a0<em>Energy and Fuels.<\/em><\/li>\n<li>C Ruan, K Yang, C Beckett, W Martin, E.D. Walter, W Hu, J Liu, N Zayan, B Lessin, J,K. Faherty, R Akutsu, J.Z. Hu, F Li. &#8220;Metal-facilitated, sustainable nitroarene hydrogenation under ambient conditions&#8221;.\u00a0<strong>2024<\/strong>. <em>Journal of Catalysis.<\/em><\/li>\n<li>V Haribal, S Iftikhar, A Tong, A Rayer, C Sanderson, F Li, L Neal. &#8220;Technoeconomic and Emissions Analysis of the Hybrid Redox Process for the Production of Acetic Acid with CO2 Utilization&#8221;.\u00a0<strong>2024<\/strong>. <em>Advanced Sustainable Systems<\/em>, 2300453<\/li>\n<li>R Cai, E Krzystowczyk, B Braunberger, F Li, L Neal. &#8220;Techno-economic analysis of chemical looping air separation using a perovskite oxide sorbent&#8221;. <strong>2024<\/strong>. <em>International Journal of Greenhouse Gas Control.\u00a0<\/em><\/li>\n<li>X Yuan, K Yang, C Grazon, C Wang, L Vallan, J-D Isasa, PM Resende, F Li, C Brochon, H Remita, G Hadziioannou, E Cloutet, J Li. &#8220;Tuning the Aggregates of Thiophene\u2010based Trimers by Methyl Side\u2010chain Engineering for Photocatalytic Hydrogen Evolution&#8221;.\u00a0<strong>2024<\/strong>. <em>Angewandte Chemie.\u00a0<\/em><\/li>\n<li>V Rahmanian, M Ziauddin A Ebrahim, S Razavi, M Abdelmigeed, E Barbieri, S Menegatti, GN Parsons, F Li, T Pirzada, SA Khan. &#8220;Vapor phase synthesis of metal\u2013organic frameworks on a nanofibrous aerogel creates enhanced functionality&#8221;.\u00a0<strong>2024<\/strong>.\u00a0<em>Journal of Materials Chemistry A.\u00a0<\/em><\/li>\n<\/ul>\n<p><span style=\"font-size: 18pt\"><strong>2023<\/strong><\/span><\/p>\n<ul>\n<li>C Ruan, R Akutsu, K Yang, NM Zayan, J Dou, J Liu, A Bose, L Brody, HH Lamb, F Li. &#8220;Hydrogenation of bio-oil-derived oxygenates at ambient conditions via a two-step redox cycle&#8221;.\u00a0<strong>2023<\/strong>. <em>Cell Reports Physical Science 4 (7)<\/em>.<\/li>\n<li>S Zhu, Y Chen, V Somayaji, P Novello, D Chacko, F Li, J Liu. &#8220;One-Step Synthesis of a High Entropy Oxide-Supported Rhodium Catalyst for Highly Selective CO Production in CO2 Hydrogenation&#8221;.\u00a0<strong>2023<\/strong>. <em>ACS Applied Materials &amp; Interfaces.<\/em><\/li>\n<li>Y Tian, PR Westmoreland, F Li. &#8220;CaMn0.9Ti0.1O3 based redox catalysts for chemical looping\u2013Oxidative dehydrogenation of ethane: Effects of Na2MoO4 promoter and degree of reduction on the reaction kinetics&#8221;. <strong>2023<\/strong>.\u00a0<em>Catalysis Today<\/em>, 417, 113725<\/li>\n<li>L Brody, M Rukh, R Cai, A Saberi Bosari, R Schom\u00e4cker, F Li. &#8220;Sorption-enhanced steam reforming of toluene using multifunctional perovskite phase transition sorbents in a chemical looping scheme&#8221;.\u00a0<strong>2023<\/strong>.\u00a0<em>Journal of Physics: Energy<\/em>.<\/li>\n<li>R Cai, L Brody, Y Tian, L Neal, A Bose, F Li. &#8220;Numerical Modeling of Chemical Looping Oxidative Dehydrogenation of Ethane in Parallel Packed Beds&#8221;. <strong>2023<\/strong>. <em>Chemical Engineering Journal<\/em>, 143930<\/li>\n<li>V Rahmanian, T Pirzada, E Barbieri, S Iftikhar, F Li, SA Khan. &#8220;Mechanically robust, thermally insulating and photo-responsive aerogels designed from sol-gel electrospun PVP-TiO2 nanofibers&#8221;.\u00a0<strong>2023<\/strong>. <em>Applied Materials Today<\/em> 32, 101784<\/li>\n<li>R Cai, H Bektas, X Wang, K McClintock, L Teague, K Yang, F Li. &#8220;Accelerated Perovskite Oxide Development for Thermochemical Energy Storage by a High\u2010Throughput Combinatorial Approach&#8221;.\u00a0<strong>2023<\/strong>. <em>Advanced Energy Materials<\/em>, 2203833<\/li>\n<\/ul>\n<p><span style=\"font-size: 18pt\"><strong>2022<\/strong><\/span><\/p>\n<ul>\n<li>S Iftikhar, W Martin, X Wang, J Liu, Y Gao, and F Li. &#8220;Ru-promoted perovskites as effective redox catalysts for CO2 splitting and methane partial oxidation in a cyclic redox scheme&#8221;.\u00a0<strong>2022<\/strong>.\u00a0<em>Nanoscale<\/em>.<\/li>\n<li>J Liu, and F. Li. &#8220;Mixed oxides as multi-functional reaction media for chemical looping catalysis&#8221;.\u00a0<strong>2022<\/strong>.\u00a0<em>Chemical Communications<\/em>.<\/li>\n<li>J Liu, S Yusuf, D Jackson, W Martin, D Chacko, K Vogt-Lowell, L Neal, and F Li. &#8220;Redox oxide@ molten salt as a generalized catalyst design strategy for oxidative dehydrogenation of ethane via selective hydrogen combustion&#8221;.\u00a0<strong>2022<\/strong>. <em>Applied Catalysis A: General.<\/em><\/li>\n<li>S Iftikhar, W Martin, Y Gao, X Yu, I Wang, Z Wu, and F Li. &#8220;LaNixFe1-xO3 as flexible oxygen or carbon carriers for tunable syngas production and CO2 utilization&#8221;.\u00a0<strong>2022<\/strong>.\u00a0<em>Catalysis Today<\/em>.<\/li>\n<li>Y Tian, G Luongo, F Donat, C Muller, Y Larring, P Westmoreland, and F Li. &#8220;Oxygen Nonstoichiometry and Defect Models of Brownmillerite-Structured Ca2MnAlO5+\u03b4 for Chemical Looping Air Separation&#8221;.\u00a0<strong>2022<\/strong>. <em>ACS Sustainable Chemistry &amp; Engineering.<\/em><\/li>\n<li>Y Gao, X Wang, N Corolla, T Eldred, A Bose, W Gao, and F Li. &#8220;Alkali metal halide\u2013coated perovskite redox catalysts for anaerobic oxidative dehydrogenation of n-butane&#8221;. <strong>2022<\/strong>.\u00a0<em>Science Advances.\u00a0<\/em><\/li>\n<li>L Brody, L Neal, J Liu, and F Li. &#8220;Autothermal Chemical Looping Oxidative Dehydrogenation of Ethane: Redox Catalyst Performance, Longevity, and Process Analysis&#8221;\u00a0<strong>2022<\/strong>.\u00a0<em>Energy and Fuels<\/em>.<\/li>\n<li>H Gu, G Song, S Zhao, Y Gao, and F Li. &#8220;Sr2CeO4 as a robust high temperature sorbent for CO2 capture with near 100% sorbent conversion efficiency&#8221; <strong>2022<\/strong>.\u00a0<em>Chemical Engineering Journal<\/em>.<\/li>\n<li>L Brody, R Cai, A Thornton, J Liu, H Yu, and F Li. &#8220;Perovskite-Based Phase Transition Sorbents for Sorption-Enhanced Oxidative Steam Reforming of Glycerol&#8221;\u00a0<strong>2022<\/strong>.\u00a0<em>ACS Sustainable Chemistry and Engineering<\/em>. 10(19).<\/li>\n<li>Y Tian, PR Westmoreland, and F Li. &#8220;CaMn0. 9Ti0. 1O3 Based Redox Catalysts for Chemical Looping\u2013Oxidative Dehydrogenation of Ethane: Effects of Na2MoO4 Promoter and Degree of Reduction on the Reaction Kinetics&#8221; <strong>2022<\/strong>.\u00a0<em>Catalysis Today<\/em>.<\/li>\n<li>X Wang, Y Gao, E Krzystowczyk,\u00a0 S Iftikhar, J Dou, R Cai, H Wang, C Ruan, S Ye, and F Li. &#8220;High-Throughput Oxygen Chemical Potential Engineering of Perovskite Oxides for Chemical Looping Applications&#8221;\u00a0<strong>2022<\/strong>.\u00a0<em>Energy and Environmental Science<\/em>. 15(4).<\/li>\n<li>C Ruan, X Wang, C Wang, L Zheng, L Li, X Liu, F Li, and X Wang. &#8220;Selective catalytic oxidation of ammonia to nitric oxide via chemical looping&#8221;\u00a0<strong>2022<\/strong>.\u00a0<em>Nature Communications.\u00a0<\/em>13(1), 1-12.<\/li>\n<li>H Gu, Y Gao, S Iftikhar, F Li. &#8220;Ce stabilized Ni-SrO as a catalytic phase transition sorbent for integrated CO2 capture and CH4 reforming&#8221; <strong>2022<\/strong>. <em>Journal of Materials Chemistry A<\/em>.<\/li>\n<\/ul>\n<p><span style=\"font-size: 18pt\"><strong>2021<\/strong><\/span><\/p>\n<ul>\n<li>S Iftikhar, Q Jiang, Y Gao, J Liu, H Gu, L Neal, F Li. &#8220;LaNi x Fe 1\u2013 x O 3\u2212\u03b4 as a Robust Redox Catalyst for CO 2 Splitting and Methane Partial Oxidation&#8221;\u00a0<strong>2021<\/strong>.\u00a0<em>Energy and Fuels<\/em>. 35(17).<\/li>\n<li>R Cai, E Krzystowczyk, A Richard, F Li. &#8220;Chemical looping air separation with Sr0. 8Ca0. 2Fe0. 9Co0. 1O3-\u03b4 perovskite sorbent: packed bed modeling, verification, and optimization&#8221;\u00a0<strong>2021<\/strong>.\u00a0<em>Chemical Engineering Journal<\/em>. 429, 132370.<\/li>\n<li>E Krzystowczyk, V Haribal, J Dou, F Li. &#8220;Chemical Looping Air Separation Using a Perovskite-Based Oxygen Sorbent: System Design and Process Analysis&#8221;\u00a0<strong>2021<\/strong>.\u00a0<em>ACS Sustainable Chemistry and Engineering<\/em>. 9(36).<\/li>\n<li>J Liu, Y Gao, X Wang, F Li. &#8220;Molten-salt-mediated carbon dioxide capture and superequilibrium utilization with ethane oxidative dehydrogenation&#8221;.\u00a0<strong>2021<\/strong>.\u00a0<em>Cell Reports Physical Science<\/em>. 2(7).<\/li>\n<li>I Wang, Y Gao, X Wang, R Cai, C Chung, S Iftikhar, W Wang, F Li. &#8220;Liquid Metal Shell as an Effective Iron Oxide Modifier for Redox-Based Hydrogen Production at Intermediate Temperatures&#8221;.\u00a0<strong>2021<\/strong>.\u00a0<em>ACS Catalysis<\/em>. 11.<\/li>\n<li>R Dudek, F Li. &#8220;Selective hydrogen combustion as an effective approach for intensified chemical production via the chemical looping strategy&#8221;.\u00a0<strong>2021<\/strong>.\u00a0<em>Fuel Processing Technology<\/em>. 218(306).<\/li>\n<li>X Zhu, Y Gao, X Wang, V Haribal, J Liu, L Neal, Z Bao, Z Wu, H Wang, F Li. &#8220;A tailored multi-functional catalyst for ultra-efficient styrene production under a cyclic redox scheme&#8221;. <strong>2021<\/strong>.\u00a0<em>Nature Communications<\/em>. 12(1).<\/li>\n<li>M Li, Y Gao, K Zhao, H Li, F He, P Lv, Z Huang. &#8220;Mg-doped La1.6Sr0.4FeCoO6 for anaerobic oxidative dehydrogenation of ethane using surface-absorbed oxygen with tuned electronic structure&#8221;. <strong>2021<\/strong>.\u00a0<em>Fuel Processing Technology<\/em>. 216, 106771.<\/li>\n<li>L Brody, L Neal, V Haribal, F Li. &#8220;Ethane to liquids via a chemical looping approach \u2013 Redox catalyst demonstration and process analysis&#8221;.\u00a0<strong>2021<\/strong>.\u00a0<em>Chemical Engineering Journal<\/em>. 417, 128886.<\/li>\n<li>F Hao, Y Gao, J Liu, R Dudek, L Neal, S Wang, P Liu, F Li. &#8220;Zeolite-assisted core-shell redox catalysts for efficient light olefin production via cyclohexane redox oxidative cracking&#8221;.\u00a0<strong>2021<\/strong>.\u00a0<em>Chemical Engineering Journal<\/em>. 409, 128192.<\/li>\n<\/ul>\n<p><span style=\"font-size: 18pt\"><strong>2020<\/strong><\/span><\/p>\n<ul>\n<li>Xiangbiao Liao, Hang Xiao, Vasudev Haribal, Xiaoyang Shi, Zhen Huang, Liangliang Zhu, Kongzhai Li, <span style=\"text-decoration: underline\">Fanxing Li<\/span>, Hua Wang, Xi Chen. &#8220;Highly efficient reduction of O2-containing CO2 via chemical looping based on perovskite nanocomposites&#8221;.\u00a0<strong>2020<\/strong>. <em>Nano Energy<\/em>. 78, 105320.<\/li>\n<li>Y Tian, RB Dudek, PR Westmoreland, F Li. &#8220;Effect of Sodium Tungstate Promoter on the Reduction Kinetics of CaMn0.9Fe0.1O3 for Chemical Looping \u2013 Oxidative Dehydrogenation of Ethane&#8221;.\u00a0<strong>2020<\/strong>.\u00a0<em>Chemical Engineering Journal.\u00a0<\/em>398, 125583.<\/li>\n<li>Y Gao, S Wang, F Hao, Z Dai, F Li. &#8220;Zeolite\u2013Perovskite Composites as Effective Redox Catalysts for Autothermal Cracking of n-Hexane&#8221;.\u00a0<strong>2020<\/strong>. <em>ACS Sustainable Chemistry &amp; Engineering<\/em>. 8 (38), 14268-14273.<\/li>\n<li>RB Dudek, Y Tian, G Jin, M Blivin, F Li. &#8220;Reduction Kinetics of Perovskite Oxides for Selective Hydrogen Combustion in the Context of Olefin Production&#8221;.\u00a0<strong>2020<\/strong>.\u00a0<em>Energy Technology<\/em>. 8 (8), 1900738.<\/li>\n<li>Amit Mishra, Arya Shafiefarhood, Jian Dou, <span style=\"text-decoration: underline\">Fanxing Li<\/span>. &#8220;Rh promoted perovskites for exceptional \u201clow temperature\u201d methane conversion to syngas&#8221;. <strong>2020<\/strong>.\u00a0<em>Catalysis Today<\/em>. 350, 149-155.<\/li>\n<li>Fang Hao, Yunfei Gao, Luke Neal, Ryan B Dudek, Wenyuan Li, Chingchang Chung, Bo Guan, Pingle Liu, Xingbo Liu, <span style=\"text-decoration: underline\">Fanxing Li<\/span>. &#8220;Sodium tungstate-promoted CaMnO3 as an effective, phase-transition redox catalyst for redox oxidative cracking of cyclohexane&#8221;.\u00a0<strong>2020<\/strong>. <em>Journal of Catalysis<\/em>. 385, 213-223.<\/li>\n<li>Jian Dou, Emily Krzystowczyk, Xijun Wang, Anthony R Richard, Thomas Robbins, <span style=\"text-decoration: underline\">Fanxing Li<\/span>. &#8220;Sr1-xCaxFe1-yCoyO3-\u03b4 as facile and tunable oxygen sorbents for chemical looping air separation&#8221;.\u00a0<strong>2020<\/strong>.\u00a0<em>Journal of Physics: Energy<\/em>. 2 (2), 025007.<\/li>\n<li>Y Gao, X Wang, J Liu, C Huang, K Zhao, Z Zhao, X Wang, F Li. &#8220;A molten carbonate shell modified perovskite redox catalyst for anaerobic oxidative dehydrogenation of ethane&#8221;.\u00a0<em>Science Advances.\u00a0<\/em><strong>2020<\/strong>. 6 (17), eaaz9339.<\/li>\n<li>Petr Novotn\u00fd, Seif Yusuf, <span style=\"text-decoration: underline\">Fanxing Li<\/span>, H Henry Lamb. &#8220;MoO3\/Al2O3 catalysts for chemical-looping oxidative dehydrogenation of ethane&#8221;.\u00a0<em>The Journal of Chemical Physics<\/em>.\u00a0<strong>2020<\/strong>. 152 (4), 044713.<\/li>\n<li>J Dou, E Krzystowczyk, X Wang, T Robbins, L Ma, X Liu, F Li. &#8220;A\u2010 and B\u2010site Codoped SrFeO3 Oxygen Sorbents for Enhanced Chemical Looping Air Separation&#8221;.\u00a0<em>ChemSusChem.\u00a0<\/em><strong>2020<\/strong>. 13 (2), 385-393.<\/li>\n<li>Q Jiang, Y Gao, VP Haribal, H Qi, X Liu, H Hong, H Jin, F Li. &#8220;Mixed conductive composites for \u2018Low-Temperature\u2019 thermo-chemical CO2 splitting and syngas generation&#8221;.\u00a0<em>Journal of Materials Chemistry A<\/em>.\u00a0<strong>2020<\/strong>. 8 (26), 13173-13182<\/li>\n<li>Emily Krzystowczyk, Xijun Wang, Jian Dou, Vasudev Haribal, <span style=\"text-decoration: underline\">Fanxing Li<\/span>. &#8220;Substituted SrFeO3 as robust oxygen sorbents for thermochemical air separation: correlating redox performance with compositional and structural properties&#8221;.\u00a0<em>Physical Chemistry Chemical Physics<\/em>.\u00a0<strong>2020<\/strong>. 22 (16), 8924-8932.<\/li>\n<li>Zachary S Campbell, Daniel Jackson, Jacob Lustik, Amur K Al-Rashdi, Jeffrey A Bennett, <span style=\"text-decoration: underline\">Fanxing Li<\/span>, Milad Abolhasani. &#8220;Continuous flow synthesis of phase transition-resistant titania microparticles with tunable morphologies&#8221;.\u00a0<em>RCS Advances<\/em>.\u00a0<strong>2020<\/strong>. 10 (14), 8340-8347.<\/li>\n<\/ul>\n<p><span style=\"font-size: 18pt\"><strong>2019<\/strong><\/span><\/p>\n<ul>\n<li>Jian Dou, Emily Krzystowczyk, Xijun Wang, Thomas Robbins, Liang Ma, Xingbo Liu, and <span style=\"text-decoration: underline\">Fanxing Li<\/span>. \u201cA and B-site Co-Doped SrFeO<sub>3<\/sub> Oxygen Sorbents for Enhanced Chemical Looping Air Separation.&#8221; <em>ChemSusChem<\/em>. In Press.<\/li>\n<li>Vasudev Haribal, Xijun Wang, Ryan Dudek, Courtney Paulus, Brian Turk, Raghubir Gupta, and <span style=\"text-decoration: underline\">Fanxing Li<\/span>. &#8220;Modified Ceria for &#8216;Low-Temperature&#8217; CO<sub>2<\/sub> Utilization: A Chemical Looping Route to Exploit Industrial Waste Heat.&#8221; <em>Advanced Energy Materials<\/em>. <strong>2019<\/strong>, 9 (41), 1901963.<\/li>\n<li>Amit Mishra, Ryan Dudek, Anne Gaffney, Dong Ding, and <span style=\"text-decoration: underline\">Fanxing Li<\/span>. &#8220;Spinel Oxides as Coke-Resistant Supports for NiO-Based Oxygen Carriers in Chemical Looping Combustion of Methane.&#8221; <em>Catalysis Today<\/em>. <strong>2019<\/strong>.<\/li>\n<li>Yunfei Gao, Luke Neal, Dong Ding, Wei Wu, Chimoy Baroi, Anne Gaffney, and <span style=\"text-decoration: underline\">Fanxing Li<\/span>. &#8220;Recent Advances in Intensified Ethylene Production &#8212; A Review.&#8221; <em>ACS Catalysis<\/em>. <strong>2019<\/strong>. 9 (9), 8592.<\/li>\n<li>Ryan B. Dudek, Yuan Tian, Gaochen Jin, Millicent Blivin, and <span style=\"text-decoration: underline\">Fanxing Li<\/span>. &#8220;Reduction Kinetics of Perovskite Oxides for Selective Hydrogen Combustion in the Context of Olefin Production.&#8221; <em>Energy Technology<\/em>. <strong>2019<\/strong>. 1900738.<\/li>\n<li>Luke Neal, Vasudev Haribal, and <span style=\"text-decoration: underline\">Fanxing Li<\/span>. &#8220;Intensified Ethylene Production via Chemical Looping through an Exergetically Efficient Redox Scheme.&#8221; <em>IScience<\/em>. <strong>2019<\/strong>. 19, 894.<\/li>\n<li>Seif Yusuf, Vasudev Haribal, Dan Jackson, Luke Neal, and <span style=\"text-decoration: underline\">Fanxing Li<\/span>. &#8220;Mixed Iron-Manganese Oxides as Redox Catalysts for Chemical Looping\u2013Oxidative Dehydrogenation of Ethane with Tailorable Heat of Reactions.&#8221; <em>Applied Catalysis B: Environmental<\/em>. <strong>2019<\/strong>, 257.<\/li>\n<li>Ryan B Dudek, Xin Tian, Millicent Blivin, Luke Neal, Haibo Zhao, and <span style=\"text-decoration: underline\">Fanxing Li<\/span>. &#8220;Perovskite oxides for redox oxidative cracking of n-hexane under a cyclic redox scheme.&#8221; <em>Applied Catalysis B: Environmental<\/em>. <strong>2019<\/strong>, 246, 30-40.<\/li>\n<li>Amit Mishra, Arya Shafiefarhood, Jian Dou, and <span style=\"text-decoration: underline\">Fanxing Li<\/span>. &#8220;Rh Promoted Perovskites for Exceptional &#8216;Low Temperature&#8217; Methane Conversion to Syngas.&#8221; <em>Catalysis Today<\/em>. <strong>2019<\/strong>.<\/li>\n<li>Luke Neal, Vasudev Haribal, Joseph McCaig, H. Henry Lamb, and <span style=\"text-decoration: underline\">Fanxing Li<\/span>. &#8220;Modular\u2010scale ethane to liquids via chemical looping oxidative dehydrogenation: Redox catalyst performance and process analysis.&#8221; <em>Journal of Advanced Manufacturing and Processing<\/em>. <strong>2019<\/strong>, 1 (1-2).<\/li>\n<li>Seif Yusuf, Luke Neal, Zhenghong Bao, Zili Wu, and <span style=\"text-decoration: underline\">Fanxing Li<\/span>. &#8220;Effects of Sodium and Tungsten Promoters on Mg<sub>6<\/sub>MnO<sub>8<\/sub>-Based Core\u2013Shell Redox Catalysts for Chemical Looping\u2014Oxidative Dehydrogenation of Ethane.&#8221; <em>ACS Catalysis<\/em>. <strong>2019<\/strong>, 9 (4), 3174-3186.<\/li>\n<li>Xin Tian, Ryan B Dudek, Yunfei Gao, Haibo Zhao, and <span style=\"text-decoration: underline\">Fanxing Li<\/span>. &#8220;Redox oxidative cracking of <em>n<\/em>-hexane with Fe-substituted barium hexaaluminates as redox catalysts.&#8221; <em>Catalysis Science &amp; Technology<\/em>. <strong>2019<\/strong>, 9 (9), 2211-2220.<\/li>\n<\/ul>\n<p><span style=\"font-size: 18pt\"><strong>2018<\/strong><\/span><\/p>\n<ul>\n<li>Amit Mishra, Tianyang Li, <span style=\"text-decoration: underline\">Fanxing Li<\/span>, and Erik Santiso. &#8220;Oxygen Vacancy Creation Energy in Mn-Containing Perovskites: An Effective Indicator for Chemical Looping with Oxygen Uncoupling.&#8221; <em>Chemistry of Materials<\/em>. <strong>2018<\/strong>, 31 (3), 689-698.<\/li>\n<li>Jian Dou, Emily Krzystowczyk, Amit Mishra, Xingbo Liu, and <span style=\"text-decoration: underline\">Fanxing Li<\/span>. &#8220;Perovskite Promoted Mixed Co-Fe Oxides for Enhanced Chemical Looping Air Separation.&#8221; <em>ACS Sustainable Chemistry &amp; Engineering<\/em>. <strong>2018<\/strong>, 6 (11), 15528-15540.<\/li>\n<li>Seif Yusuf, Luke M Neal, Vasudev P Haribal, Madison Baldwin, H. Henry Lamb, and <span style=\"text-decoration: underline\">Fanxing Li<\/span>. &#8220;Manganese silicate based redox catalysts for greener ethylene production via chemical looping-oxidative dehydrogenation of ethane.&#8221; <em>Applied Catalysis B: Environmental<\/em>. <strong>2018<\/strong>, 232, 77-85.<\/li>\n<li>Vasudev P Haribal, Yun Chen, Luke M Neal, and <span style=\"text-decoration: underline\">Fanxing Li<\/span>. &#8220;Intensification of Ethylene Production from Naphtha via a Redox Oxy-Cracking Scheme: Process Simulations and Analysis.&#8221; <em>Engineering<\/em>. <strong>2018<\/strong>, 4 (5), 714-721.<\/li>\n<li>Xing Zhu, Kongzhai Li, Luke M Neal, and <span style=\"text-decoration: underline\">Fanxing Li<\/span>. &#8220;Perovskites as Geo-Inspired Oxygen Storage Materials for Chemical Looping and Three-Way Catalysis: A Perspective.&#8221; <em>ACS Catalysis<\/em>. <strong>2018<\/strong>, 8 (9), 8213-8236.<\/li>\n<li>Amit Mishra and <span style=\"text-decoration: underline\">Fanxing Li<\/span>. &#8220;Chemical looping at the nanoscale &#8212; challenges and opportunities.&#8221; <em>Current Opinion in Chemical Engineering<\/em>. <strong>2018<\/strong>, 20, 143-150.<\/li>\n<li>Ryan B Dudek, Yunfei Gao, Junshe Zhang, and <span style=\"text-decoration: underline\">Fanxing Li<\/span>. &#8220;Manganese-Containing Redox Catalysts for Selective Hydrogen Combustion under a Cyclic Redox Scheme.&#8221; <em>AIChE Journal<\/em>. <strong>2018<\/strong>, 64 (8), 3141-3150.<\/li>\n<li>Yunfei Gao, Farrah Haeri, Fang He, and <span style=\"text-decoration: underline\">Fanxing Li<\/span>. &#8220;Alkali Metal-Promoted La<sub>x<\/sub>Sr<sub>2-x<\/sub>FeO<sub>4-d<\/sub> Redox Catalysts for Chemical Looping Oxidative Dehydrogenation of Ethane.&#8221; <em>ACS Catalysis<\/em>. <strong>2018<\/strong>, 8 (3), 1757-1766.<\/li>\n<\/ul>\n<p><span style=\"font-size: 18pt\"><strong>2017<\/strong><\/span><\/p>\n<ul>\n<li>Vasudev P Haribal, Feng He, Amit Mishra, and <u>Fanxing Li<\/u>. &#8220;Iron-Doped BaMnO<sub>3<\/sub> for Hybrid Water Splitting and Syngas Generation.&#8221; <em>ChemSusChem<\/em>. <strong>2017<\/strong>, 10, 1-8.<\/li>\n<li>Junshe Zhang, Vasudev Haribal, and <u>Fanxing Li<\/u><em>.<\/em> &#8220;Perovskite nanocomposites as effective CO<sub>2<\/sub>-splitting agents in a cyclic redox scheme.&#8221; <em>Science Advances<\/em>. <strong>2017<\/strong>, 3 (8), e1701184.<\/li>\n<li>Seif Yusuf, Luke M Neal, and <u>Fanxing Li<\/u>. &#8220;Effect of Promoters on Manganese-Containing Mixed Metal Oxides for Oxidative Dehydrogenation of Ethane via a Cyclic Redox Scheme.&#8221; <em>ACS Catalysis<\/em>. <strong>2017<\/strong>, 7, 5163-5173.<\/li>\n<li>Feng He, William P Linak, Shuang Deng, and <u>Fanxing Li<\/u>. &#8220;Particulate Formation from a Copper Oxide-Based Oxygen Carrier in Chemical Looping Combustion for CO<sub>2<\/sub> Capture.&#8221; <em>Environmental Science and Technology<\/em>. <strong>2017<\/strong>, 51 (4), 2482-2490.<\/li>\n<li>Vasudev P Haribal, Luke M Neal, and <u>Fanxing Li<\/u>. &#8220;Oxidative dehydrogenation of ethane under a cyclic redox scheme &#8212; Process simulations and analysis.&#8221; <em>Energy<\/em>. <strong>2017<\/strong>, 119, 1024-1035.<\/li>\n<li>Arya Shafiefarhood, Junshe Zhang, Luke M Neal, and <u>Fanxing Li<\/u>. &#8220;Rh-promoted mixed oxides for &#8220;low-temperature&#8221; methane partial oxidation in the absence of gaseous oxidants.&#8221; <em>Journal of Material Chemistry A<\/em>. <strong>2017<\/strong>, 5, 11930-11939.<\/li>\n<\/ul>\n<p><span style=\"font-size: 18pt\"><strong>2016<\/strong><\/span><\/p>\n<ul>\n<li>Luke M Neal, Seif Yusuf, John A Sofranko, and <u>Fanxing Li<\/u>. &#8220;Oxidative Dehydrogenation of Ethane: A Chemical Looping Approach.&#8221; <em>Energy Technology<\/em>. <strong>2016<\/strong>, 4 (10), 1200-1208.<\/li>\n<li>Yunfei Gao, Luke M Neal, and <u>Fanxing Li<\/u>. &#8220;Li-Promoted La<sub>x<\/sub>Sr<sub>2-x<\/sub>FeO<sub>4-d<\/sub> Core-Shell Redox Catalysts for Oxidative Dehydrogenation of Ethane under a Cyclic Redox Scheme.&#8221; <em>ACS Catalysis<\/em>. <strong>2016<\/strong>, 6, 7293-7302.<\/li>\n<li>Nathan Galinsky, Marwan Sendi, Lindsay Bowers, and <u>Fanxing Li<\/u>. &#8220;CaMn<sub>1-x<\/sub>B<sub>x<\/sub>O<sub>3-d<\/sub> (B= Al, V, Fe, Co, and Ni) perovskite based oxygen carriers for chemical looping with oxygen uncoupling (CLOU).&#8221; <em>Applied Energy<\/em>. <strong>2016<\/strong>, 174, 80-87.<\/li>\n<li>Amit Mishra, Nathan Galinsky, Feng He, Erik Sansiso, and <u>Fanxing Li<\/u>. &#8220;Perovskite-structured AMn<sub>x<\/sub>B<sub>1-x<\/sub>O<sub>3<\/sub> (A= Ca or Ba; B= Fe or Ni) redox catalysts for partial oxidation of methane.&#8221; <em>Catal. Sci. Technol.<\/em> <strong>2016<\/strong>, DOI: 10.1039\/C5CY02186C.<\/li>\n<li>J. Zachary Mundy, Arya Shafiefarhood, <u>Fanxing Li<\/u>, Saad Khan, and Gregory Parsons. &#8220;Low temperature platinum atomic layer deposition on nylon-6 for highly conductive and catalytic fiber mats.&#8221; <em>J. Vac. Sci. Technol<\/em>. <strong>2016<\/strong>, A 34, 01A152.<\/li>\n<\/ul>\n<p><span style=\"font-size: 18pt\"><strong>2015<\/strong><\/span><\/p>\n<ul>\n<li>Arya Shafiefarhood, J. Clay Hamill, Luke Neal, and <u>Fanxing Li<\/u>. &#8220;Methane partial oxidation using FeO<sub>x<\/sub>@La<sub>0.8<\/sub>Sr<sub>0.2<\/sub>FeO<sub>3-\u03b4<\/sub>core-shell catalyst &#8211; transient pulse studies.&#8221; <em>Phys. Chem. Chem. Phys<\/em>. <strong>2015<\/strong>, 17, 31297-31307.<\/li>\n<li>Junshe Zhang and <u>Fanxing Li<\/u>. &#8220;Coke-resistant Ni@SiO2 catalyst for dry reforming of methane.&#8221; <em>Applied Catalysis B: Environmental<\/em>. <strong>2015<\/strong>, 176-177, 513-521.<\/li>\n<li>Luke Neal, Arya Shafiefarhood, and <u>Fanxing Li<\/u>. &#8220;Effect of Core and Shell Compositions on MeO<sub>x<\/sub>@La<sub>y<\/sub>Sr<sub>1-y<\/sub>FeO<sub>3<\/sub> Core-Shell Redox Catalysts for Chemical Looping Reforming of Methane.&#8221; <em>Applied Energy.<\/em>\u00a0<strong>2015<\/strong>, doi:10.1016\/j.apenergy.2015.06.028.<\/li>\n<li>Nathan Galinsky, Amit Mishra, Jia Zhang, and <u>Fanxing Li<\/u>. &#8220;Ca<sub>1-x<\/sub>A<sub>x<\/sub>MnO<sub>3<\/sub> (A= Sr and Ba) Perovskite Based Oxygen Carriers for Chemical Looping with Oxygen Uncoupling (CLOU).&#8221; <em>Applied Energy<\/em>. <strong>2015<\/strong> doi:10.1016\/j.apenergy.2015.04.020.<\/li>\n<li>Feng He and <u>Fanxing Li<\/u>. &#8220;Perovskite promoted iron oxide for hybrid water-splitting and syngas generation with exceptional conversion.&#8221; <em>Energy and Environmental Science<\/em>. <strong>2015<\/strong>, 8(2), 535-539.<\/li>\n<\/ul>\n<p><span style=\"font-size: 18pt\"><strong>2014<\/strong><\/span><\/p>\n<ul>\n<li>Nathan Galinsky, Arya Shafiefarhood, Yanguang Chen, Luke Neal, <u>Fanxing Li<\/u> &#8220;Effect of support on redox stability of iron oxide for chemical looping conversion of methane&#8221;. Applied Catalysis B: Environmental. 2014, 164, 371-379.<\/li>\n<li>Luke Neal, Arya Shafiefarhood, <u>Fanxing Li<\/u> &#8220;Dynamic methane partial oxidation using a Fe<sub>2<\/sub>O<sub>3<\/sub>@La<sub>0.8<\/sub>Sr<sub>0.2<\/sub>FeO<sub>3-d<\/sub> Core-Shell redox catalyst in absence of gaseous oxygen&#8221;. ACS Catalysis. 2014, 4(10), 3560-3569.<\/li>\n<li>Arya Shafiefarhood, Amy Stewart, <u>Fanxing Li<\/u> &#8220;Iron-Containing Mixed-Oxide Composites as Oxygen Carriers for Chemical Looping with Oxygen Uncoupling (CLOU)&#8221;. Fuel. 2015, 139, 1-10<\/li>\n<li>Yanguang Chen, Feng He, Shivalik Daga, <u>Fanxing Li<\/u> &#8220;Redox conversion of methane with Fe2O3-CaTixM1-xO3 composite oxides for hydrogen and liquid fuel co-production&#8221;. Journal of Chemical Industry and Engineering(China), (In Chinese, Festschrift for Prof. Yong Jin)<\/li>\n<li>Yanguang Chen, Nathan L Galinsky, Ziren Wang, <u>Fanxing Li<\/u> &#8220;Investigation of Perovskite Supported Composite Oxides for Chemical Looping Conversion of Syngas&#8221;. Fuel. 2014, 134, 521-530<\/li>\n<li>Feng He and <u>Fanxing Li<\/u> &#8220;Hydrogen production from methane and solar energy &#8211; process evaluations and comparison studies&#8221;. International Journal of Hydrogen Energy. 2014, 39(31), 18092-18102.<\/li>\n<li>Feng He, James Trainham, Gregory Parsons, John S. Newmanbc, and <u>Fanxing Li<\/u> &#8220;A hybrid solar-redox scheme for liquid fuel and hydrogen coproduction&#8221;. Energy and Environmental Science. 2014, 7, 2033-2042.<\/li>\n<li>Phillip N. Pressley, Tarek N. Aziz, Joseph F. DeCarolis, Morton A. Barlaz, Feng He, <u>Fanxing Li<\/u>, Anders Damgaardc &#8220;Municipal solid waste conversion to transportation fuels: a life-cycle estimation of global warming potential and energy consumption&#8221;. Journal of Cleaner Production. 2014, 70: 145-153.<\/li>\n<li>Arya Shafiefarhood, Nathan Galinsky, Yan Huang, Yanguang Chen, and <u>Fanxing Li<\/u> &#8220;Fe2O3@LaxSr1-xFeO3 Core-Shell Redox Catalyst for Chemical Looping Reforming of Methane&#8221;. ChemCatChem. 2014, 6(3): 790-799.<\/li>\n<li>Yang Liu, Weiwei Hu, Kelly Wiltberger, Thomas Ryll, and <u>Fanxing Li<\/u> &#8220;Effects of Bubble-Liquid Two-Phase Turbulent Hydrodynamics on Cell Damage in Sparged Bioreactor&#8221;. Biotechnology Progress, 2014, 30(1): 48-58.<\/li>\n<\/ul>\n<p><span style=\"font-size: 18pt\"><strong>2013<\/strong><\/span><\/p>\n<ul>\n<li>Feng He, nathan Galinsky, <u>Fanxing Li<\/u>. &#8220;Chemical looping gasification of solid fuels using bimetallic oxygen carrier particles &#8211; Feasibility assessment and process simulations&#8221; Int. J. Hydrog. Energy, 2013, 38(19): 7839-7854<\/li>\n<li>Nathan Galinsky, Yan Huang, Arya Shafiefarhood, <u>Fanxing Li<\/u>. &#8220;Iron Oxide with Facilitated O2- Transport for Facile Fuel Oxidation and CO2 Capture in a Chemical Looping Scheme.&#8221; Acs Sustain. Chem. Eng. 2013, 1, 364-373.<\/li>\n<\/ul>\n<p><span style=\"font-size: 18pt\"><strong>2012<\/strong><\/span><\/p>\n<ul>\n<li>Liang Zeng, Feng He, <u>Fanxing Li<\/u>, and L.-S. Fan. &#8220;Coal-Direct Chemical Looping Gasification for Hydrogen Production: Reactor Modeling and Process Simulation.&#8221; Energy and Fuels. 2012, 26, 3680-3690.<\/li>\n<li>Deepak Shridhar, Andrew Tong, Hyung Ray Kim, Liang Zeng, <u>Fanxing Li<\/u>, and L.-S. Fan. &#8220;syngas chemical looping process: design and construction of a 25kwth sub-pilot unit.&#8221; Energy Fuels, 2012, 26 (4), 2292-2302<\/li>\n<li>Liang Zeng, Siwei Luo, <u>Fanxing Li<\/u>, and L.-S. Fan. &#8220;Chemical looping technology and its applications in fossil fuel conversion and CO2 capture.&#8221; Science China Chemistry. 2012, 42(3): 260-281 (in Chinese).<\/li>\n<\/ul>\n<p><span style=\"font-size: 18pt\"><strong>2011 and earlier<\/strong><\/span><\/p>\n<ul>\n<li><u>Fanxing Li<\/u>, Siwei Luo, Zhenchao Sun, and L.-S. Fan. &#8220;Role of Metal Oxide Support in Redox Reactions of Iron Oxide for Chemical Looping Applications: Experiments and Density Functional Theory Calculations.&#8221; Energy and Environmental Science. 2011, 4: 3661-3667.<\/li>\n<li>Zhenchao Sun, Fu-Chen Yu, <u>Fanxing Li<\/u>, Songgeng Li, and Liang-Shih Fan. &#8220;Experimental Study of HCl Capture Using CaO Sorbents: Activation, Deactivation, Reactivation, and Ionic Transfer Mechanism&#8221; Industrial and Engineering Chemistry Research. 2011, 50(10): 6034-6043.<\/li>\n<li><u>Fanxing Li<\/u>, Zhenchao Sun, Siwei Luo, and L.-S. Fan. &#8220;Ionic Diffusion in Iron Oxidation &#8211; Effect of Support and Its Implications to Chemical Looping Applications&#8221; Energy and Environmental Science. 2011, 4, 876-880.<\/li>\n<li><u>Fanxing Li<\/u>, Liang Zeng, and L.-S. Fan. &#8220;Biomass Direct Chemical Looping Process: Process Simulations&#8221;, Fuel, 2010, 89(12): 3773 &#8211; 3784.<\/li>\n<li><u>Fanxing Li<\/u>, Liang Zeng, Luis G. Velazquez-Vargas, Zack Yosevich, and L.-S. Fan. &#8220;Syngas Chemical Looping Gasification Process: Bench Studies and Reactor Simulations&#8221;, AIChE Journal. 2010, 56(8): 2186-2199.<\/li>\n<li><u>Fanxing Li<\/u>, Hyung Rae Kim, Deepak Sridhar, Fei Wang, Liang Zeng, and L.-S. Fan. &#8220;Syngas Chemical Looping Gasification Process: Oxygen Carrier Particle Selection and Performance.&#8221; Energy and Fuel, 2009, 23(8): 4182 &#8211; 4189.<\/li>\n<li><u>Fanxing Li<\/u>, Liang Zeng, and L.-S. Fan. &#8220;Techno-Economic Analysis of Coal Based Hydrogen and Electricity Co-Generation Processes with CO2 Capture&#8221;, Industrial and Engineering Chemistry Research. 2010, 49 (21), 11018 &#8211; 11028.<\/li>\n<li>L.-S. Fan and <u>Fanxing Li<\/u>. &#8220;Chemical Looping Technology and Its Fossil Energy Conversion Applications&#8221;, Industrial and Engineering Chemistry Research. 2010, 49 (21), 10200 &#8211; 10211.<\/li>\n<li><u>Fanxing Li<\/u>, L.-S. Fan. &#8220;Clean Coal Conversion Processes &#8211; Progress and Challenges.&#8221; Energy and Environmental Science. 2008, 1:248-267. (Rated as &#8220;most downloaded article&#8221; in 2008 &#8211; 2009 by RSC)<\/li>\n<li>L.-S. Fan, <u>Fanxing Li<\/u>, Shwetha Ramkumar. &#8220;Utilization of Chemical Looping in Coal Gasification Processes.&#8221; Particuology (on coverpage), 2008, 6(3):131-142.<\/li>\n<li><u>Fanxing Li<\/u>, Yao Wang, Dezheng Wang, Fei Wei. &#8220;Characterization of single-wall carbon nanotubes by N2 adsorption.&#8221; Carbon, 2004, 42: 2375-2383.<\/li>\n<li>Dezheng Wang, <u>Fanxing Li<\/u>, Xueliang Zhao. &#8220;Diffusion Limitation in Fast Transient Experiments.&#8221; Chemical Engineering Science. 59(2004), 5615-5622.<\/li>\n<li>Xueliang Zhao, <u>Fanxing Li<\/u>, Dezheng Wang. &#8220;Comparison of Microkinetics and Langmuir -Hinshelwood Models of the Partial Oxidation of Methane to Synthesis Gas.&#8221; Studies in Surface Science and Catalysis. 2004, 147: 235-240.<\/li>\n<\/ul>\n<h3><span style=\"color: #000000\">Book Chapters and Magazine Articles<\/span><\/h3>\n<ul>\n<li>Yunfei Gao, Fanxing Li. &#8220;Natural Gas Conversion&#8221; in Direct Natural Gas Conversion to Value-Added Chemicals.<\/li>\n<li>L.-S. Fan, <u>Fanxing Li<\/u>. &#8220;Clean Coal.&#8221; Physics World. July (The Institute of Physics Publishing), 2007.<\/li>\n<li><u>Fanxing Li<\/u>, Fei Wang, Deepak Sridhar, Hyung-Rae Kim, Luis G. Velazquez-Vargas, and Liang-Shih Fan. &#8220;Chemical Looping Combustion&#8221; in Chemical Looping Systems for Fossil Energy Conversions.<\/li>\n<li><u>Fanxing Li<\/u>, Liang Zeng, Shwetha Ramkumar, Mahesh Iyer, and Liang-Shih Fan. &#8220;Chemical Looping Gasification Using Gaseous Fuels&#8221; in Chemical Looping Systems for Fossil Energy Conversions.<\/li>\n<li><u>Fanxing Li<\/u>, Luis G. Velazquez-Vargas, Liang Zeng, Deepak Sridhar, and Liang-Shih Fan. &#8220;Chemical Looping Gasification Using Solid Fuels&#8221; in Chemical Looping Systems for Fossil Energy Conversions.<\/li>\n<li>Puneet Gupta, <u>Fanxing Li<\/u>, L. G. Velazquez-Vargas, Deepak Sridhar, Mahesh Iyer, S. Ramkumar, and Liang-Shih Fan. &#8220;Chemical Looping Particles&#8221; in Chemical Looping Systems for Fossil Energy Conversions.<\/li>\n<li>Ah-Hyung Alissa Park, Puneet Gupta, <u>Fanxing Li<\/u>, Deepak Sridhar, and Liang-Shih Fan. &#8220;Novel Application of Chemical Looping Technologies&#8221; in Chemical Looping Systems for Fossil Energy Conversions.<\/li>\n<\/ul>\n<h3><span style=\"color: #000000\">Patents and Patent Applications<\/span><\/h3>\n<ul>\n<li>L.-S. Fan, Reddy Karri, <u>Fanxing Li<\/u>, John Findlay, Ted Knowlton, Fei Wang, Ray Cocco, Andrew Tong. Circulating Fluidized Bed with Moving Bed Downcomers and Gas Sealing Between Reactors. Jointly filed between OSU and Particulate Solid Research Inc. (Filed on 11\/05\/2010)<\/li>\n<li>L.-S. Fan, <u>Fanxing Li<\/u>, Liang Zeng. Synthetic Fuels and Chemicals Production with in-situ CO2 Capture. PCT\/US10\/48121. 2009.<\/li>\n<li>L.-S. Fan, <u>Fanxing Li<\/u>, Liang Zeng, Deepak Sridhar. Integration of Reforming\/Water Splitting and Electrochemical Systems for Power Generation with Integrated Carbon Capture. PCT\/US10\/48125. 2009. (Various companies including Shell and Babcock &amp; Wilcox have shown interest on the two aforementioned patents. Collaborative development agreement has been signed with Shell and is being negotiated with B&amp;W)<\/li>\n<li>L.-S. Fan, <u>Fanxing Li<\/u>. Methods to Convert Carbonaceous Fuels into Carbon Free Energy Carriers. WO 2010037011. PCT Int. Appl., WO 2010037011, 2008. (Licensed to Industrial Technology Research Institute)<\/li>\n<li>L.-S. Fan, Puneet Gupta, Luis G Velazquez-Vargas, <u>Fanxing Li<\/u>. Systems and Methods of Converting Fuels. PCT Int. Appl. WO 2007082089, 2007.<\/li>\n<li>L.-S. Fan, Deepak Sridhar, and Fanxing Li. &#8220;Oxygen Carrying Materials&#8221;. PCT. WO 2,012,155,059.<\/li>\n<li>L.-S. Fan, Puneet Gupta, Luis G Velazquez-Vargas, Fanxing Li. &#8220;Systems and Methods of Converting Fuels&#8221;. PCT. WO 2007082089, 2007.<\/li>\n<li>Fanxing Li and Yanguang Chen. &#8220;Mixed-Conductor Enhanced Composite and Core-Shell Oxides for Cyclic Redox Productions of Fuels and Chemicals&#8221;. US 61\/923,939, 2014.<\/li>\n<li>Fanxing Li, Jim Trainham, Feng He, Greg Parsons, and John Newman. &#8220;Hybrid Redox Systems and Methods and Oxygen Carriers for Use Therein For Fuel Production&#8221;. US 61\/973,670, 2014.<\/li>\n<li>Fanxing Li, Weiwei Hu, Yang Liu, and Kelly Wiltberger. &#8220;Bioreactor Gas Sparging and in-situ Hold-Up Monitoring System&#8221;. Jan. 2014.<\/li>\n<li>John Sofranko and Fanxing Li. &#8220;Improved Electrogenerative Process&#8221;. US 61\/927,220, 2014.<\/li>\n<li>L.-S. Fan, Fanxing Li, Liang Zeng, and Deepak Sridhar. &#8220;Integration of reforming\/water splitting and electrochemical systems for power generation with integrated carbon capture.&#8221; US 15\/162,199, 2016.<\/li>\n<li>Fanxing Li, Xing Zhu, Yunfei Gao. &#8220;Materials and methods for oxidative dehydrogenation of alkyl aromatic compounds involving lattice oxygen of transition metal oxides&#8221;. US20200009539A1, 2020.<\/li>\n<li>Fanxing Li, Luke M Neal. &#8220;Ethylene yield in oxidative dehydrogenation of ethane and ethane containing hydrocarbon mixtures<br \/>\nAbstract&#8221;. 10550051, 2020.<\/li>\n<li>F Li, LM Neal, Y Gao, S Yusuf, R Dudek. &#8220;Oxygen carrying materials with surface modification for redox-based catalysis and methods of making and uses thereof&#8221;. US20200215515A1, 2020.<\/li>\n<li>LS Fan, F Li, L Zeng. &#8220;Synthetic fuels and chemicals production with in-situ CO2 capture&#8221;. US10865346B2, 2020.<\/li>\n<\/ul>\n","protected":false},"excerpt":{"rendered":"<p>Journal Publications 2026 SB Portillo, M Kosari, F Li. \u201cSupported Transition Metals for Catalytic Decomposition of Methane: Advances, Challenges, and Outlook\u201d 2026. ACS Catalysis. 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