Intermetallic compounds: promising inorganic materials for well-structured and electronically modified reaction environments for efficient catalysis S Furukawa, T Komatsu Acs Catalysis 7 (1), 735-765, 2017 | 420 | 2017 |
Selective Amine Oxidation Using Nb2O5 Photocatalyst and O2 S Furukawa, Y Ohno, T Shishido, K Teramura, T Tanaka ACS Catalysis 1 (10), 1150-1153, 2011 | 283 | 2011 |
Towards the Circular Economy: Converting Aromatic Plastic Waste Back to Arenes over a Ru/Nb2O5 Catalyst Y Jing, Y Wang, S Furukawa, J Xia, C Sun, MJ Hülsey, H Wang, Y Guo, ... Angewandte Chemie International Edition 60 (10), 5527-5535, 2021 | 202 | 2021 |
Single-atom Pt in intermetallics as an ultrastable and selective catalyst for propane dehydrogenation Y Nakaya, J Hirayama, S Yamazoe, K Shimizu, S Furukawa Nature communications 11 (1), 2838, 2020 | 199 | 2020 |
Efficient catalytic system for chemoselective hydrogenation of halonitrobenzene to haloaniline using PtZn intermetallic compound S Iihama, S Furukawa, T Komatsu ACS Catalysis 6 (2), 742-746, 2016 | 162 | 2016 |
Photocatalytic Oxidation of Alcohols over TiO2 Covered with Nb2O5 S Furukawa, T Shishido, K Teramura, T Tanaka Acs Catalysis 2 (1), 175-179, 2012 | 147 | 2012 |
Density functional theory calculations of oxygen vacancy formation and subsequent molecular adsorption on oxide surfaces Y Hinuma, T Toyao, T Kamachi, Z Maeno, S Takakusagi, S Furukawa, ... The Journal of Physical Chemistry C 122 (51), 29435-29444, 2018 | 133 | 2018 |
Chemoselective hydrogenation of nitrostyrene to aminostyrene over Pd-and Rh-based intermetallic compounds S Furukawa, Y Yoshida, T Komatsu ACS Catalysis 4 (5), 1441-1450, 2014 | 121 | 2014 |
A Cu–Pd single-atom alloy catalyst for highly efficient NO reduction F Xing, J Jeon, T Toyao, K Shimizu, S Furukawa Chemical science 10 (36), 8292-8298, 2019 | 118 | 2019 |
Highly efficient aerobic oxidation of various amines using Pd 3 Pb intermetallic compounds as catalysts S Furukawa, A Suga, T Komatsu Chemical communications 50 (25), 3277-3280, 2014 | 114 | 2014 |
Factors affecting coke formation on H-ZSM-5 in naphtha cracking R Javaid, K Urata, S Furukawa, T Komatsu Applied Catalysis A: General 491, 100-105, 2015 | 109 | 2015 |
Organonitrogen chemicals from oxygen-containing feedstock over heterogeneous catalysts Y Wang, S Furukawa, X Fu, N Yan ACS Catalysis 10 (1), 311-335, 2019 | 103 | 2019 |
Selective Hydrogenation of Functionalized Alkynes to (E)-Alkenes, Using Ordered Alloys as Catalysts S Furukawa, T Komatsu ACS Catalysis 6 (3), 2121-2125, 2016 | 103 | 2016 |
Catalytic production of alanine from waste glycerol Y Wang, S Furukawa, S Song, Q He, H Asakura, N Yan Angewandte Chemie 132 (6), 2309-2313, 2020 | 93 | 2020 |
Location of coke on H-ZSM-5 zeolite formed in the cracking of n-hexane K Urata, S Furukawa, T Komatsu Applied Catalysis A: General 475, 335-340, 2014 | 92 | 2014 |
Ternary platinum–cobalt–indium nanoalloy on ceria as a highly efficient catalyst for the oxidative dehydrogenation of propane using CO2 F Xing, Y Nakaya, S Yasumura, K Shimizu, S Furukawa Nature Catalysis 5 (1), 55-65, 2022 | 89 | 2022 |
Rhenium‐Loaded TiO2: A Highly Versatile and Chemoselective Catalyst for the Hydrogenation of Carboxylic Acid Derivatives and the N‐Methylation of Amines Using H2 and … T Toyao, SMAH Siddiki, Y Morita, T Kamachi, AS Touchy, W Onodera, ... Chemistry–A European Journal 23 (59), 14848-14859, 2017 | 88 | 2017 |
Atomic Pd-promoted ZnZrOx solid solution catalyst for CO2 hydrogenation to methanol K Lee, U Anjum, TP Araújo, C Mondelli, Q He, S Furukawa, ... Applied Catalysis B: Environmental 304, 120994, 2022 | 87 | 2022 |
Well-structured bimetallic surface capable of molecular recognition for chemoselective nitroarene hydrogenation S Furukawa, K Takahashi, T Komatsu Chemical Science 7 (7), 4476-4484, 2016 | 87 | 2016 |
PtCu intermetallic compound supported on alumina active for preferential oxidation of CO in hydrogen T Komatsu, M Takasaki, K Ozawa, S Furukawa, A Muramatsu The Journal of Physical Chemistry C 117 (20), 10483-10491, 2013 | 84 | 2013 |