Study of oxygen evolution reaction on amorphous Au13@Ni120P50 nanocluster
The pursuit of catalysts to promote effective water oxidization to produce oxygen has become a research subject of high priority for water splitting. Here, first-principles calculations are employed to study the water-splitting oxygen evolution reaction (OER) on ∼1.5 nm diameter Au 13 @Ni 120 P 50 c...
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| Published in | Physical chemistry chemical physics : PCCP Vol. 2; no. 21; pp. 14545 - 14556 |
|---|---|
| Main Authors | , , , , , , , , |
| Format | Journal Article |
| Language | English |
| Published |
Cambridge
Royal Society of Chemistry
2018
|
| Subjects | |
| Online Access | Get full text |
| ISSN | 1463-9076 1463-9084 1463-9084 |
| DOI | 10.1039/c8cp00784e |
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| Abstract | The pursuit of catalysts to promote effective water oxidization to produce oxygen has become a research subject of high priority for water splitting. Here, first-principles calculations are employed to study the water-splitting oxygen evolution reaction (OER) on ∼1.5 nm diameter Au
13
@Ni
120
P
50
core-shell nanoclusters. Water splitting to produce oxygen proceeds in four intermediate reaction steps (OH*, O*, OOH* and O
2
). Adsorption configurations and adsorption energies for the species involved in OER on both Au
13
@Ni
120
P
50
cluster and Ni
12
P
5
(001) supported by Au are presented. In addition, thermodynamic free energy diagrams and kinetic potential energy changes are systematically discussed. We show that the third intermediate reaction (O* reacting with H
2
O to produce OOH*) of the four elementary steps is the reaction-determining step, which accords with previous results. Also, the catalytic performance of OER for Au
13
@Ni
120
P
50
is better than that for Ni
12
P
5
(001) supported by Au in terms of reactive overpotential (0.74
vs.
1.58 V) and kinetic energy barrier (2.18
vs.
3.17 eV). The optimal kinetic pathway for OER is further explored carefully for the Au
13
@Ni
120
P
50
cluster. The low thermodynamic overpotential and kinetic energy barrier make Au
13
@Ni
120
P
50
promising for industrial applications as a good OER electrocatalyst candidate.
Potential energy changes of the four consecutive elementary reaction steps for OER on the surfaces of both bumpy Au
13
@Ni
120
P
50
nanocluster and clean Ni
12
P
5
(001) supported by bulk Au, respectively. |
|---|---|
| AbstractList | The pursuit of catalysts to promote effective water oxidization to produce oxygen has become a research subject of high priority for water splitting. Here, first-principles calculations are employed to study the water-splitting oxygen evolution reaction (OER) on ∼1.5 nm diameter Au
13
@Ni
120
P
50
core-shell nanoclusters. Water splitting to produce oxygen proceeds in four intermediate reaction steps (OH*, O*, OOH* and O
2
). Adsorption configurations and adsorption energies for the species involved in OER on both Au
13
@Ni
120
P
50
cluster and Ni
12
P
5
(001) supported by Au are presented. In addition, thermodynamic free energy diagrams and kinetic potential energy changes are systematically discussed. We show that the third intermediate reaction (O* reacting with H
2
O to produce OOH*) of the four elementary steps is the reaction-determining step, which accords with previous results. Also, the catalytic performance of OER for Au
13
@Ni
120
P
50
is better than that for Ni
12
P
5
(001) supported by Au in terms of reactive overpotential (0.74
vs.
1.58 V) and kinetic energy barrier (2.18
vs.
3.17 eV). The optimal kinetic pathway for OER is further explored carefully for the Au
13
@Ni
120
P
50
cluster. The low thermodynamic overpotential and kinetic energy barrier make Au
13
@Ni
120
P
50
promising for industrial applications as a good OER electrocatalyst candidate.
Potential energy changes of the four consecutive elementary reaction steps for OER on the surfaces of both bumpy Au
13
@Ni
120
P
50
nanocluster and clean Ni
12
P
5
(001) supported by bulk Au, respectively. The pursuit of catalysts to promote effective water oxidization to produce oxygen has become a research subject of high priority for water splitting. Here, first-principles calculations are employed to study the water-splitting oxygen evolution reaction (OER) on ∼1.5 nm diameter Au13@Ni120P50 core-shell nanoclusters. Water splitting to produce oxygen proceeds in four intermediate reaction steps (OH*, O*, OOH* and O2). Adsorption configurations and adsorption energies for the species involved in OER on both Au13@Ni120P50 cluster and Ni12P5(001) supported by Au are presented. In addition, thermodynamic free energy diagrams and kinetic potential energy changes are systematically discussed. We show that the third intermediate reaction (O* reacting with H2O to produce OOH*) of the four elementary steps is the reaction-determining step, which accords with previous results. Also, the catalytic performance of OER for Au13@Ni120P50 is better than that for Ni12P5(001) supported by Au in terms of reactive overpotential (0.74 vs. 1.58 V) and kinetic energy barrier (2.18 vs. 3.17 eV). The optimal kinetic pathway for OER is further explored carefully for the Au13@Ni120P50 cluster. The low thermodynamic overpotential and kinetic energy barrier make Au13@Ni120P50 promising for industrial applications as a good OER electrocatalyst candidate.The pursuit of catalysts to promote effective water oxidization to produce oxygen has become a research subject of high priority for water splitting. Here, first-principles calculations are employed to study the water-splitting oxygen evolution reaction (OER) on ∼1.5 nm diameter Au13@Ni120P50 core-shell nanoclusters. Water splitting to produce oxygen proceeds in four intermediate reaction steps (OH*, O*, OOH* and O2). Adsorption configurations and adsorption energies for the species involved in OER on both Au13@Ni120P50 cluster and Ni12P5(001) supported by Au are presented. In addition, thermodynamic free energy diagrams and kinetic potential energy changes are systematically discussed. We show that the third intermediate reaction (O* reacting with H2O to produce OOH*) of the four elementary steps is the reaction-determining step, which accords with previous results. Also, the catalytic performance of OER for Au13@Ni120P50 is better than that for Ni12P5(001) supported by Au in terms of reactive overpotential (0.74 vs. 1.58 V) and kinetic energy barrier (2.18 vs. 3.17 eV). The optimal kinetic pathway for OER is further explored carefully for the Au13@Ni120P50 cluster. The low thermodynamic overpotential and kinetic energy barrier make Au13@Ni120P50 promising for industrial applications as a good OER electrocatalyst candidate. The pursuit of catalysts to promote effective water oxidization to produce oxygen has become a research subject of high priority for water splitting. Here, first-principles calculations are employed to study the water-splitting oxygen evolution reaction (OER) on ∼1.5 nm diameter Au13@Ni120P50 core–shell nanoclusters. Water splitting to produce oxygen proceeds in four intermediate reaction steps (OH*, O*, OOH* and O2). Adsorption configurations and adsorption energies for the species involved in OER on both Au13@Ni120P50 cluster and Ni12P5(001) supported by Au are presented. In addition, thermodynamic free energy diagrams and kinetic potential energy changes are systematically discussed. We show that the third intermediate reaction (O* reacting with H2O to produce OOH*) of the four elementary steps is the reaction-determining step, which accords with previous results. Also, the catalytic performance of OER for Au13@Ni120P50 is better than that for Ni12P5(001) supported by Au in terms of reactive overpotential (0.74 vs. 1.58 V) and kinetic energy barrier (2.18 vs. 3.17 eV). The optimal kinetic pathway for OER is further explored carefully for the Au13@Ni120P50 cluster. The low thermodynamic overpotential and kinetic energy barrier make Au13@Ni120P50 promising for industrial applications as a good OER electrocatalyst candidate. |
| Author | Qian, Ping Huo, Jinrong Li, Lu Su, Yanjing Wang, Xiaoxu Volinsky, Alex A Wang, Yanzhou Zhang, Yajing Gao, Panpan |
| AuthorAffiliation | Advanced Material and Technology Institute Department of Mechanical Engineering University of Science and Technology Beijing University of South Florida Department of Physics |
| AuthorAffiliation_xml | – name: University of Science and Technology Beijing – name: Department of Physics – name: Department of Mechanical Engineering – name: University of South Florida – name: Advanced Material and Technology Institute |
| Author_xml | – sequence: 1 givenname: Yanzhou surname: Wang fullname: Wang, Yanzhou – sequence: 2 givenname: Panpan surname: Gao fullname: Gao, Panpan – sequence: 3 givenname: Xiaoxu surname: Wang fullname: Wang, Xiaoxu – sequence: 4 givenname: Jinrong surname: Huo fullname: Huo, Jinrong – sequence: 5 givenname: Lu surname: Li fullname: Li, Lu – sequence: 6 givenname: Yajing surname: Zhang fullname: Zhang, Yajing – sequence: 7 givenname: Alex A surname: Volinsky fullname: Volinsky, Alex A – sequence: 8 givenname: Ping surname: Qian fullname: Qian, Ping – sequence: 9 givenname: Yanjing surname: Su fullname: Su, Yanjing |
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| SubjectTerms | Adsorption Catalysis Clusters First principles Free energy Industrial applications Kinetic energy Nanoclusters Oxygen evolution reactions Potential energy Water splitting |
| Title | Study of oxygen evolution reaction on amorphous Au13@Ni120P50 nanocluster |
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