|Understanding catalytic activity trends in the oxygen reduction reaction|
A Kulkarni, S Siahrostami, A Patel, JK NÝrskov
Chemical Reviews 118 (5), 2302-2312, 2018
|High-efficiency oxygen reduction to hydrogen peroxide catalysed by oxidized carbon materials|
Z Lu, G Chen, S Siahrostami, Z Chen, K Liu, J Xie, L Liao, T Wu, D Lin, ...
Nature Catalysis 1 (2), 156-162, 2018
|Enabling direct H2O2 production through rational electrocatalyst design|
S Siahrostami, A Verdaguer-Casadevall, M Karamad, D Deiana, ...
Nature materials 12 (12), 1137-1143, 2013
|Isolated Ni single atoms in graphene nanosheets for high-performance CO 2 reduction|
K Jiang, S Siahrostami, T Zheng, Y Hu, S Hwang, E Stavitski, Y Peng, ...
Energy & Environmental Science 11 (4), 893-903, 2018
|The oxygen reduction reaction mechanism on Pt (1 1 1) from density functional theory calculations|
V Tripković, E Skķlason, S Siahrostami, JK NÝrskov, J Rossmeisl
Electrochimica Acta 55 (27), 7975-7981, 2010
|Trends in the Electrochemical Synthesis of H2O2: Enhancing Activity and Selectivity by Electrocatalytic Site Engineering|
A Verdaguer-Casadevall, D Deiana, M Karamad, S Siahrostami, ...
Nano letters 14 (3), 1603-1608, 2014
|Electrochemical ammonia synthesis via nitrate reduction on Fe single atom catalyst|
ZY Wu, M Karamad, X Yong, Q Huang, DA Cullen, P Zhu, C Xia, Q Xiao, ...
Nature communications 12 (1), 2870, 2021
|Highly selective oxygen reduction to hydrogen peroxide on transition metal single atom coordination|
K Jiang, S Back, AJ Akey, C Xia, Y Hu, W Liang, D Schaak, E Stavitski, ...
Nature communications 10 (1), 3997, 2019
|Understanding activity trends in electrochemical water oxidation to form hydrogen peroxide|
X Shi, S Siahrostami, GL Li, Y Zhang, P Chakthranont, F Studt, ...
Nature communications 8 (1), 701, 2017
|Introducing Fe2+ into Nickel–Iron Layered Double Hydroxide: Local Structure Modulated Water Oxidation Activity|
Z Cai, D Zhou, M Wang, SM Bak, Y Wu, Z Wu, Y Tian, X Xiong, Y Li, W Liu, ...
Angewandte Chemie 130 (30), 9536-9540, 2018
|Transition-metal single atoms in a graphene shell as active centers for highly efficient artificial photosynthesis|
K Jiang, S Siahrostami, AJ Akey, Y Li, Z Lu, J Lattimer, Y Hu, C Stokes, ...
Chem 3 (6), 950-960, 2017
|Designing boron nitride islands in carbon materials for efficient electrochemical synthesis of hydrogen peroxide|
S Chen, Z Chen, S Siahrostami, D Higgins, D Nordlund, D Sokaras, ...
Journal of the American Chemical Society 140 (25), 7851-7859, 2018
|Beyond the top of the volcano?–A unified approach to electrocatalytic oxygen reduction and oxygen evolution|
M Busch, NB Halck, UI Kramm, S Siahrostami, P Krtil, J Rossmeisl
Nano Energy 29, 126-135, 2016
|Building and identifying highly active oxygenated groups in carbon materials for oxygen reduction to H2O2|
GF Han, F Li, W Zou, M Karamad, JP Jeon, SW Kim, SJ Kim, Y Bu, Z Fu, ...
Nature Communications 11 (1), 2209, 2020
|Defective carbon-based materials for the electrochemical synthesis of hydrogen peroxide|
S Chen, Z Chen, S Siahrostami, TR Kim, D Nordlund, D Sokaras, ...
ACS Sustainable Chemistry & Engineering 6 (1), 311-317, 2018
|One- or Two-Electron Water Oxidation, Hydroxyl Radical, or H2O2 Evolution|
S Siahrostami, GL Li, V Viswanathan, JK NÝrskov
The journal of physical chemistry letters 8 (6), 1157-1160, 2017
|Confined local oxygen gas promotes electrochemical water oxidation to hydrogen peroxide|
C Xia, S Back, S Ringe, K Jiang, F Chen, X Sun, S Siahrostami, K Chan, ...
Nature Catalysis 3 (2), 125-134, 2020
|A review on challenges and successes in atomic-scale design of catalysts for electrochemical synthesis of hydrogen peroxide|
S Siahrostami, SJ Villegas, AH Bagherzadeh Mostaghimi, S Back, ...
ACS Catalysis 10 (14), 7495-7511, 2020
|Promoting H2O2 production via 2-electron oxygen reduction by coordinating partially oxidized Pd with defect carbon|
Q Chang, P Zhang, AHB Mostaghimi, X Zhao, SR Denny, JH Lee, H Gao, ...
Nature communications 11 (1), 2178, 2020
|Monocopper active site for partial methane oxidation in Cu-exchanged 8MR zeolites|
AR Kulkarni, ZJ Zhao, S Siahrostami, JK NÝrskov, F Studt
Acs Catalysis 6 (10), 6531-6536, 2016