A Universal Method to Engineer Metal Oxide–Metal–Carbon Interface for Highly Efficient Oxygen Reduction

Li, Lin; Zha, Dace; Ruan, Yunjun; Li, Zhishan; Ao, Xiang; Zheng, Jianlong; Jiang, Jianjun; Chen, Hao Ming; Chiang, Wei‐Hung; Chen, Jun; Wang, Chundong

doi:10.1021/acsnano.8b01056

Cited by 129 publications

(88 citation statements)

References 67 publications

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“…This speculation can be supported by the previous reported CeO x /M (M = Pt and Co etc.) studies 42,67,68. For example, DFT calculations by Kim et al, demonstrated that CeO 2 can perturbe the electronic structure of Co species and further optimize the binding energy of intermediate oxygenated adsorbates 69.…”

Section: Resultsmentioning

confidence: 99%

Gadolinium‐Induced Valence Structure Engineering for Enhanced Oxygen Electrocatalysis

Wang

Yang

et al. 2020

Advanced Energy Materials

121

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Rare earth doped materials with unique electronic ground state configurations are considered emerging alternatives to conventional Pt/C for the oxygen reduction reaction (ORR). Herein, gadolinium (Gd)‐induced valence structure engineering is, for the first, time investigated for enhanced oxygen electrocatalysis. The Gd2O3–Co heterostructure loaded on N‐doped graphene (Gd2O3–Co/NG) is constructed as the target catalyst via a facile sol–gel assisted strategy. This synthetic strategy allows Gd2O3–Co nanoparticles to distribute uniformly on an N‐graphene surface and form intimate Gd2O3/Co interface sites. Upon the introduction of Gd2O3, the ORR activity of Gd2O3–Co/NG is significantly increased compared with Co/NG, where the half‐wave potential (E1/2) of Gd2O3–Co/NG is 100 mV more positive than that of Co/NG and even close to commercial Pt/C. The density functional theory calculation and spectroscopic analysis demonstrate that, owing to intrinsic charge redistribution at the engineered interface of Gd2O3/Co, the coupled Gd2O3–Co can break the OOH*–OH* scaling relation and result in a good balance of OOH* and OH* binding on Gd2O3–Co surface. For practical application, a rechargeable Zn–air battery employing Gd2O3–Co/NG as an air–cathode achieves a large power density and excellent charge–discharge cycle stability.

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Section: Resultsmentioning

confidence: 99%

Gadolinium‐Induced Valence Structure Engineering for Enhanced Oxygen Electrocatalysis

Wang

Yang

et al. 2020

Advanced Energy Materials

121

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“…The oxygen vacancy/defect has been studied in the ORR process and verified as the most active adsorption sites 19,138. The high‐resolution Ce 3d spectrum in a metal oxide–metal–carbon interface nanostructure (CeO 2 ‐Co‐NC) showed the existence of Ce 2+ and Ce 3+ ( Figure 8 a),19 in which Ce 3+ led to the charge imbalance and created oxygen vacancies 19. The DFT simulation method136 can be applied to clarify the ORR mechanism and the role of the oxygen vacancy as shown in Figure 8b–e, revealing that the charge redistribution between CeO 2 and metallic Co has led to an electron‐rich region on CeO 2 and a hole‐rich region on the Co, corresponding to the new Ce 3+ peak in the partial density of states around the Fermi level.…”

Section: Orr Performance and Active Site Researchmentioning

confidence: 99%

“…The adsorption of the oxygen molecule at the initial step is believed one of the rate‐determining steps in the ORR process as shown in Equations and , which is especially of vital importance for the metal oxide catalysts. The oxygen vacancy/defect has been studied in the ORR process and verified as the most active adsorption sites 19,138. The high‐resolution Ce 3d spectrum in a metal oxide–metal–carbon interface nanostructure (CeO 2 ‐Co‐NC) showed the existence of Ce 2+ and Ce 3+ ( Figure 8 a),19 in which Ce 3+ led to the charge imbalance and created oxygen vacancies 19.…”

Section: Orr Performance and Active Site Researchmentioning

confidence: 99%

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Efficient Oxygen Reduction Catalysts of Porous Carbon Nanostructures Decorated with Transition Metal Species

Huang

Shen

Zhang

et al. 2019

Advanced Energy Materials

182

122

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Developing substitutes of noble metal catalysts toward oxygen reduction reaction (ORR) at the cathode is of vital importance for promoting low‐temperature polymer electrolyte membrane fuel cells. Transition metal species have been one of the hot areas of interest due to their low cost, high activity, and long‐term stability. The design of porous carbon nanostructures decorated with transition metal species plays a vital role in enhancing ORR catalytic performance. Here, the recent breakthroughs in porous carbon nanostructures decorated with transition metal species (including nanoparticles and atomically dispersed supported metal) are discussed. The porous nanostructures can provide large surface area as well as abundant pore channels, leading to sufficient exposure of active sites and efficient mass transfer. These nanostructures can be synthesized by several approaches, including the templated method, the self‐templated method, the impregnation process, and so on. Furthermore, the ORR performance and the exploration of active sites are also discussed for further enhancement of the ORR catalysts. Finally, the challenges and prospects are discussed, which would push forward the development of ORR catalysts in the near future.

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“…Especially, CeO 2 is possible to stabilize more nitrogen sources during catalyst synthesis process . Furthermore, it is worth mentioning that there also exists an electronic interaction between CeO 2 and metal in the co‐synthesized catalyst, which may enhance the oxygen absorption on the catalyst for improved ORR activity . Besides, CeO 2 can effectively catalyze the decomposition of H 2 O 2 , which is very favorable for the retention of active sites in ORR catalysts, thereby improving the long‐term stability .…”

Section: Introductionmentioning

confidence: 99%

Fabricating Nitrogen‐Rich Fe−N/C Electrocatalysts through CeO₂‐Assisted Pyrolysis for Enhanced Oxygen Reduction Reaction

et al. 2019

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The electrochemical oxygen reduction reaction (ORR) is a central process of various energy conversion systems. Yet, searching non‐noble‐metal electrocatalysts with superior ORR performance is still a great challenge. Herein, CeO2‐loaded Fe−N/C catalysts (Fe−N/C−CeO2) were prepared through a facile hydrothermal and pyrolysis method for enhanced ORR properties. The proper amount of CeO2 can induce the anchoring of N species during the pyrolysis process, and increase the N‐containing active sites such as Fe−Nx. Moreover, CeO2 nanoparticles are capable of rapidly reducing the H2O2 intermediate in ORR, further boosting the durability of the catalyst. Consequently, the Fe−N/C−CeO2 (1 %) catalyst delivers prominent ORR performance with a half‐wave potential of 0.862 V and a diffusion limiting current density of 5.51 mA cm−2 in 0.1 M KOH, which is superior than that of the Fe−N/C catalyst, and even comparable to that of commercial Pt/C catalyst. Furthermore, the long‐term stability test of Fe−N/C−CeO2 (1 %) shows a negative shift of just 18 mV of the half‐wave potential after 10000 cycles, which is much smaller than that of the Fe−N/C sample.

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A Universal Method to Engineer Metal Oxide–Metal–Carbon Interface for Highly Efficient Oxygen Reduction

Cited by 129 publications

References 67 publications

Gadolinium‐Induced Valence Structure Engineering for Enhanced Oxygen Electrocatalysis

Gadolinium‐Induced Valence Structure Engineering for Enhanced Oxygen Electrocatalysis

Efficient Oxygen Reduction Catalysts of Porous Carbon Nanostructures Decorated with Transition Metal Species

Fabricating Nitrogen‐Rich Fe−N/C Electrocatalysts through CeO₂‐Assisted Pyrolysis for Enhanced Oxygen Reduction Reaction

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A Universal Method to Engineer Metal Oxide–Metal–Carbon Interface for Highly Efficient Oxygen Reduction

Cited by 129 publications

References 67 publications

Gadolinium‐Induced Valence Structure Engineering for Enhanced Oxygen Electrocatalysis

Gadolinium‐Induced Valence Structure Engineering for Enhanced Oxygen Electrocatalysis

Efficient Oxygen Reduction Catalysts of Porous Carbon Nanostructures Decorated with Transition Metal Species

Fabricating Nitrogen‐Rich Fe−N/C Electrocatalysts through CeO2‐Assisted Pyrolysis for Enhanced Oxygen Reduction Reaction

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Fabricating Nitrogen‐Rich Fe−N/C Electrocatalysts through CeO₂‐Assisted Pyrolysis for Enhanced Oxygen Reduction Reaction