Original Papers- TODOROKI Naoto -
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[2020]
1.Dry synthesis of single-nanometer-scale Pt Si fine particles for electrocatalysis.[Journal of Electroanalytical Chemistry,(2020),114492]Naoto Todoroki, Shuntaro Takahashi, Kotaro Kawaguchi, Yusuke Fugane, Toshimasa Wadayama
10.1016/j.jelechem.2020.114492
2.Online Electrochemical Mass Spectrometry Combined with the Rotating Disk Electrode Method for Direct Observations of Potential-Dependent Molecular Behaviors in the Electrode Surface Vicinity.[Journal of The Electrochemical Society,167(10),(2020),106503]Naoto Todoroki, Hiroto Tsurumaki, Hiroki Tei, Tomohiro Mochizuki, Toshimasa Wadayama
10.1149/1945-7111/ab9960
3.Model building analysis – a novel method for statistical evaluation of Pt L3-edge EXAFS data to unravel the structure of Pt-alloy nanoparticles for the oxygen reduction reaction on highly oriented pyrolytic graphite.[Physical Chemistry Chemical Physics,(2020)]F. E. Feiten, S. Takahashi, O. Sekizawa, Y. Wakisaka, T. Sakata, N. Todoroki, T. Uruga, T. Wadayama, Y. Iwasawa, K. Asakura
[2019]
4.Heterolayered Ni–Fe Hydroxide/Oxide Nanostructures Generated on a Stainless-Steel Substrate for Efficient Alkaline Water Splitting.[ACS Applied Materials & Interfaces,(11),(2019),44161-44169]Naoto Todoroki, Toshimasa Wadayama
5.Effective Surface Termination with Au on PtCo@Pt Core-Shell Nanoparticle: Microstructural Investigations and Oxygen Reduction Reaction Properties.[Journal of Electroanalytical Chemistry,842(1),(2019),1-7]Shuntaro Takahashi, Naoto Todoroki, Rikiya Myochi, Tetsuro Nagao, Noboru Taguchi, Tsutomu Ioroi, Felix E. Feiten, Yuki Wakisaka, Kiyotaka Asakura, Oki Sekizawa, Tomohiro Sakata, Kotaro Higashi, Tomoya Uruga, YasuhiroIwasawa, Toshimasa Wadayama
6.Electrochemical CO2 Reduction on Bimetallic Surface Alloys: Enhanced Selectivity to CO for Co/Au(110) and to H2 for Sn/Au(110).[ChemElectroChem,6(12),(2019),3101-3107]Naoto Todoroki, Hiroki Tei, Taku Miyakawa , Hiroto Tsurumaki , Toshimasa Wadayama
7.Ligand-Effect-Induced Oxygen Reduction Reaction Activity Enhancement for Pt/Zr/Pt(111) Surfaces with Tensile Strain Relieved by Stacking Faults.[ACS Applied Energy Materials,(2019)]Daisuke Kudo, Soma Kaneko, Rikiya Myochi, Yoshihiro Chida, Naoto Todoroki, Tadao Tanabe, Toshimasa Wadayama
8.Surface Atomic Arrangement Dependence of Electrochemical CO2 Reduction on Gold: Online Electrochemical Mass Spectrometric Study on Low-Index Au(hkl) Surfaces.[ACS Catalysis,9,(2019),1383-1388]N. Todoroki, H. Tei, H. Tsurumaki, T.Miyakawa, T. Inoue and T. Wadayama
[2018]
9.Oxygen Reduction and Oxygen Evolution Reaction Activity on Co/Pt (111) Surfaces in Alkaline Solution.[ECS Transactions,86(13),(2018),569-574]N Todoroki, T Wadayama
10.1149/08613.0569ecst
10.Oxygen Reduction Reaction Properties of Dry-Process-Synthesized Pt/Graphene/SiC (0001) Model Catalyst Surfaces.[ECS Transactions,86(13),(2018),525-530]M Watanabe, J Moon, T Tanabe, N Todoroki, T Wadayama
10.1149/08613.0525ecst
11.Rotating Disk Electrode–Online Electrochemical Mass Spectrometry for Oxygen Reduction Reaction on Pt Electrode Surfaces.[ECS Transaction,86(13),(2018),447-452]H Tsurumaki, T Mochizuki, H Tei, N Todoroki, T Wadayama
10.1149/08613.0447ecst
12.Oxygen Reduction Reaction Properties for Dry-Process Synthesized Pt/TaCx Nanoparticles.[ECS Transactions,86(13),(2018),519-524]R Myochi, T Nagao, Y Fugane, S Takahashi, N Todoroki, T Wadayama
10.1149/08613.0519ecst
13.Oxygen Reduction Reaction Activity for Cobalt-Deposited Pt (111) Model Catalyst Surfaces in Alkaline Solution.[Electrochemistry,86(5),(2018),243-245]N. Todoroki and T. Wadayama
14.歪み制御した単結晶Ptシェルの酸素還元反応活性.[燃料電池,18,(2018),73-79]金子聡真, 妙智力也, 渡邉裕文, 番土陽平, 高橋俊太郎, 轟直人, 田邉匡生, 和田山智正
15.Alloy-composition-dependent oxygen reduction reaction activity and electrochemical stability of Pt-based bimetallic systems: a model electrocatalyst study of Pt/PtxNi100-x(111).[Physical Chemistry Chemical Physics,20(17),(2018),1994-12004]Naoto Todoroki, Ryutaro Kawamura, Masato Asano, Ren Sasakawa, Shuntaro Takahashi, Toshimasa Wadayama
16.Alloy-composition-dependent oxygen reduction reaction activity and electrochemical stability of Pt-based bimetallic systems: a model electrocatalyst study of Pt/PtxNi100−x(111).[Physical Chemistry Chemical Physics,(2018)]Naoto Todoroki, Ryutaro Kawamura, Masato Asano, Ren Sasakawa, Shuntaro Takahashi, Toshimasa Wadayama
10.1039/c8cp01217b
[2017]
17.Ultrahigh Vacuum Synthesis of Strain-Controlled Model Pt (111)-Shell Layers: Surface Strain and Oxygen Reduction Reaction Activity.[The Journal of Physical Chemistry Letters,8(21),(2017),5360-5365]S. Kaneko, R. Myochi, S. Takahashi, N. Todoroki, T. Wadayama, and T. Tanabe
18.Electrochemical Stability of Pt/Pd (111) Model Core-Shell Structure in 80° C Perchloric Acid.[Journal of The Electrochemical Society,164(9),(2017),F908-F910]N Todoroki, Y Bando, Y Tani, S Kaneko, H Watanabe, S Takahashi, T Wadayama
19.Communication-Electrochemical Stability of Pt/Pd(111) Model Core-Shell Structure in 80 degrees C Perchloric Acid.[JOURNAL OF THE ELECTROCHEMICAL SOCIETY,164(9),(2017),F908-F910]N. Todoroki, Y. Bando, Y. Tani, S. Kaneko, H. Watanabe, S. Takahashi, T. Wadayama
10.1149/2.0571709jes
http://gateway.isiknowledge.com/gateway/Gateway.cgi?&GWVersion=2&SrcAuth=TohokuUniv&SrcApp=TohokuUniv&DestLinkType=FullRecord&KeyUT=WOS:000413256400151&DestApp=WOS
[2016]
20.Dealloying of Nitrogen-Introduced Pt–Co Alloy Nanoparticles: Preferential Core–Shell Formation with Enhanced Activity for Oxygen Reduction Reaction.[ACS Omega,1(6),(2016),1247-1252]S. Takahashi, N. Takahashi, N. Todoroki, T. Wadayama
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