Electrochemical Ammonia Synthesis—The Selectivity Challenge

Singh, Aayush R.; Rohr, Brian A.; Schwalbe, Jay A.; Cargnello, Matteo; Chan, Karen; Jaramillo, Thomas F.; Chorkendorff, Ib; Nørskov, Jens K.

doi:10.1021/acscatal.6b03035

articleACS CatalysisDec 7, 2016GREEN OA

Electrochemical Ammonia Synthesis—The Selectivity Challenge

ARAayush R. Singh BABrian A. Rohr JAJay A. Schwalbe MCMatteo Cargnello KCKaren Chan

Interface (United States) · Stanford University · +2 more institutions

Indexed incrossref

Abstract

Here, the N2 molecule is particularly inert; the N–N triple bond is one of the most stable in all of chemistry, and in addition, the molecule has no dipole moment and a very low polarizability.

Citation impact

958

total citations

FWCI: 22.41
Percentile: 100%
References: 38

Citations per year

Authors

AR
Aayush R. SinghCorresponding
Interface (United States), Stanford University
BA
Brian A. Rohr
Interface (United States), Stanford University
JA
Jay A. Schwalbe
Interface (United States), Stanford University
MC
Matteo Cargnello
Interface (United States), Stanford University
KC
Karen Chan
SLAC National Accelerator Laboratory, Interface (United States), Stanford University

Topics & keywords

Topics

Ammonia Synthesis and Nitrogen Reduction100%
Advanced Photocatalysis Techniques99%
Catalytic Processes in Materials Science98%

Keywords

Citation
Library science
Computer science
World Wide Web

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Funding

NS
National Science Foundation
Awards: DGE-1656518, -1656518, 1656518
UD
U.S. Department of Energy
Awards: 76SF00515, DE-AC02, AC02-76SF00515, DE-AC02-
VF
Villum Fonden
OO
Office of Science
Awards: AC02-76SF00515, DE-AC02-76SF00515, DE-AC02, 76SF00515
DO
Division of Graduate Education
Award: DGE-1656518
BE
Basic Energy Sciences
Awards: DE-AC02, DE-AC02-76SF00515, 76SF00515, AC02-76SF00515