| Core–shell structured catalysts for thermocatalytic, photocatalytic, and electrocatalytic conversion of CO 2 S Das, J Pérez-Ramírez, J Gong, N Dewangan, K Hidajat, BC Gates, ... Chemical Society Reviews 49 (10), 2937-3004, 2020 | 684 | 2020 |
| A Review on Bimetallic Nickel‐Based Catalysts for CO2 Reforming of Methane Z Bian, S Das, MH Wai, P Hongmanorom, S Kawi ChemPhysChem 18 (22), 3117-3134, 2017 | 557 | 2017 |
| Silica–Ceria sandwiched Ni core–shell catalyst for low temperature dry reforming of biogas: Coke resistance and mechanistic insights S Das, J Ashok, Z Bian, N Dewangan, MH Wai, Y Du, A Borgna, K Hidajat, ... Applied Catalysis B: Environmental 230, 220-236, 2018 | 456 | 2018 |
| Recent progress in the development of catalysts for steam reforming of biomass tar model reaction J Ashok, N Dewangan, S Das, P Hongmanorom, MH Wai, K Tomishige, ... Fuel Processing Technology 199, 106252, 2020 | 177 | 2020 |
| Reforming of tar from biomass gasification in a hybrid catalysis-plasma system: A review L Liu, Z Zhang, S Das, S Kawi Applied Catalysis B: Environmental 250, 250-272, 2019 | 163 | 2019 |
| Silica-based micro-and mesoporous catalysts for dry reforming of methane Z Li, S Das, P Hongmanorom, N Dewangan, MH Wai, S Kawi Catalysis Science & Technology 8 (11), 2763-2778, 2018 | 153 | 2018 |
| Role of lattice oxygen in methane activation on Ni-phyllosilicate@ Ce1-xZrxO2 core-shell catalyst for methane dry reforming: Zr doping effect, mechanism, and kinetic study S Das, A Jangam, S Jayaprakash, S Xi, K Hidajat, K Tomishige, S Kawi Applied Catalysis B: Environmental 290, 119998, 2021 | 140 | 2021 |
| A High-Performance, Low-Tortuosity Wood-Carbon Monolith Reactor. Y Wang, G Sun, J Dai, G Chen, J Morgenstern, S Kang, M Zhu, S Das, ... Advanced Materials (Deerfield Beach, Fla.) 29 (2), 2016 | 131 | 2016 |
| Conversion of CO2 to C1 chemicals: catalyst design, kinetics and mechanism aspects of the reactions A Jangam, S Das, N Dewangan, P Hongmanorom, WM Hui, S Kawi Catalysis Today 358, 3-29, 2020 | 116 | 2020 |
| Effect of Partial Fe Substitution in La0.9Sr0.1NiO3 Perovskite-Derived Catalysts on the Reaction Mechanism of Methane Dry Reforming S Das, S Bhattar, L Liu, Z Wang, S Xi, JJ Spivey, S Kawi ACS Catalysis 10 (21), 12466-12486, 2020 | 108 | 2020 |
| LaNiO3 as a precursor of Ni/La2O3 for reverse water-gas shift in DBD plasma: Effect of calcination temperature L Liu, Z Zhang, S Das, S Xi, S Kawi Energy Conversion and Management 206, 112475, 2020 | 95 | 2020 |
| Cobalt‐Based catalyst supported on different morphologies of alumina for non‐oxidative propane dehydrogenation: Effect of metal support interaction and lewis acidic sites N Dewangan, J Ashok, M Sethia, S Das, S Pati, H Kus, S Kawi ChemCatChem 11 (19), 4923-4934, 2019 | 94 | 2019 |
| Highly dispersed Ni/silica by carbonization–calcination of a chelated precursor for coke-free dry reforming of methane S Das, A Jangam, S Xi, A Borgna, K Hidajat, S Kawi ACS Applied Energy Materials 3 (8), 7719-7735, 2020 | 82 | 2020 |
| Low temperature catalytic reverse water-gas shift reaction over perovskite catalysts in DBD plasma L Liu, S Das, T Chen, N Dewangan, J Ashok, S Xi, A Borgna, Z Li, S Kawi Applied Catalysis B: Environmental 265, 118573, 2020 | 81 | 2020 |
| H2S and NOx tolerance capability of CeO2 doped La1− xCexCo0. 5Ti0. 5O3− δ perovskites for steam reforming of biomass tar model reaction J Ashok, S Das, N Dewangan, S Kawi Energy Conversion and Management: X 1, 100003, 2019 | 65 | 2019 |
| Bi-functional CeO2 coated NiCo-MgAl core-shell catalyst with high activity and resistance to coke and H2S poisoning in methane dry reforming S Das, KH Lim, TZH Gani, S Aksari, S Kawi Applied Catalysis B: Environmental 323, 122141, 2023 | 60 | 2023 |
| Zr–Ce-incorporated Ni/SBA-15 catalyst for high-temperature water gas shift reaction: Methane suppression by incorporated Zr and Ce P Hongmanorom, J Ashok, S Das, N Dewangan, Z Bian, G Mitchell, S Xi, ... Journal of catalysis 387, 47-61, 2020 | 58 | 2020 |
| Catalytic mixed conducting ceramic membrane reactors for methane conversion Z Wang, T Chen, N Dewangan, Z Li, S Das, S Pati, Z Li, JYS Lin, S Kawi Reaction Chemistry & Engineering 5 (10), 1868-1891, 2020 | 54 | 2020 |
| Incinerator bottom ash derived from municipal solid waste as a potential catalytic support for biomass tar reforming J Ashok, S Das, TY Yeo, N Dewangan, S Kawi Waste Management 82, 249-257, 2018 | 54 | 2018 |
| High oxygen permeable and CO2-tolerant SrCoxFe0. 9-xNb0. 1O3-δ (x= 0.1–0.8) perovskite membranes: Behavior and mechanism Z Wang, N Dewangan, S Das, MH Wai, S Kawi Separation and Purification Technology 201, 30-40, 2018 | 50 | 2018 |
