Your search keyword '"Maoyu, Wang"' showing total 9 results

1. Surface oxygenation induced strong interaction between Pd catalyst and functional support for zinc–air batteries

Author

Wei Zhang, Jinfa Chang, Guanzhi Wang, Zhao Li, Maoyu Wang, Yuanmin Zhu, Boyang Li, Hua Zhou, Guofeng Wang, Meng Gu, Zhenxing Feng, and Yang Yang

Subjects

Nuclear Energy and Engineering, Renewable Energy, Sustainability and the Environment, Environmental Chemistry, Pollution

Abstract

The surface oxygenated PdNiMnO-PF was used as a bifunctional catalyst for zinc–air batteries.

Published

2022

2. Atomically dispersed single Ni site catalysts for high-efficiency CO2 electroreduction at industrial-level current densities

Author

Yi Li, Nadia Mohd Adli, Weitao Shan, Maoyu Wang, Michael J. Zachman, Sooyeon Hwang, Hassina Tabassum, Stavros Karakalos, Zhenxing Feng, Guofeng Wang, Yuguang C. Li, and Gang Wu

Subjects

Nuclear Energy and Engineering, Renewable Energy, Sustainability and the Environment, Environmental Chemistry, Pollution

Abstract

Single metal site Ni–N–C catalysts were designed concerning the particle size, metal content, and coordination structure for efficient CO2 reduction.

Published

2022

3. Interfacial processes in electrochemical energy systems

Author

Maoyu Wang and Zhenxing Feng

Subjects

Materials science, Metals and Alloys, General Chemistry, Electrolyte, Electrochemistry, Electrochemical energy conversion, Catalysis, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Ion, Electron transfer, Chemical engineering, Ion adsorption, Desorption, Electrode, Materials Chemistry, Ceramics and Composites

Abstract

Electrochemical energy systems such as batteries, water electrolyzers, and fuel cells are considered as promising and sustainable energy storage and conversion devices due to their high energy densities and zero or negative carbon dioxide emission. However, their widespread applications are hindered by many technical challenges, such as the low efficiency and poor long-term cyclability, which are mostly affected by the changes at the reactant/electrode/electrolyte interfaces. These interfacial processes involve ion/electron transfer, molecular/ion adsorption/desorption, and complex interface restructuring, which lead to irreversible modifications to the electrodes and the electrolyte. The understanding of these interfacial processes is thus crucial to provide strategies for solving those problems. In this review, we will discuss different interfacial processes at three representative interfaces, namely, solid-gas, solid-liquid, and solid-solid, in various electrochemical energy systems, and how they could influence the performance of electrochemical systems.

Published

2021

4. Doping-modulated strain control of bifunctional electrocatalysis for rechargeable zinc–air batteries

Author

Huajun Tian, Zhao Li, Xiaowan Bai, Duojie Wu, Yuanyue Liu, Qi Wang, George E. Sterbinsky, Fuping Pan, Zhenxing Feng, Maoyu Wang, Zhenzhen Yang, Zhenzhong Yang, Yingge Du, Yang Yang, and Meng Gu

Subjects

Materials science, Dopant, Renewable Energy, Sustainability and the Environment, Nanoporous, Doping, chemistry.chemical_element, Electrocatalyst, Pollution, chemistry.chemical_compound, Strain engineering, Nuclear Energy and Engineering, Chemical engineering, chemistry, Environmental Chemistry, Bifunctional, Cobalt, Current density

Abstract

Changes in the local atomic arrangement in a crystal caused by lattice-mismatch-induced strain can efficiently regulate the performance of electrocatalysts for zinc–air batteries (ZABs) in many manners, mainly due to modulated electronic structure configurations that affect the adsorption energies for oxygen-intermediates formed during oxygen reduction and evolution reactions (ORR and OER). However, the application of strain engineering in electrocatalysis has been limited by the strain relaxation caused by structural instability such as dissolution and destruction, leading to insufficient durability towards the ORR/OER. Herein, we propose a doping strategy to modulate the phase transition and formation of self-supported cobalt fluoride–sulfide (CoFS) nanoporous films using a low amount of copper (Cu) as a dopant. This well-defined Cu–CoFS heterostructure overcomes the obstacle of structural instability. Our study of the proposed Cu–CoFS also helps establish the structure–property relationship of strained electrocatalysts by unraveling the role of local strain in regulating the electronic structure of the catalyst. As a proof-of-concept, the Cu–CoFS electrocatalyst with doping-modulated strain exhibited superior onset potentials of 0.91 V and 1.49 V for the ORR and OER, respectively, surpassing commercial Pt/C@RuO2 and benchmarking non-platinum group metal (non-PGM) catalysts. ZABs with the Cu–CoFS catalyst delivered excellent charge/discharge cycling performance with an extremely low voltage gap of 0.5 V at a current density of 10 mA cm−2 and successively 0.93 V at a high current density of 100 mA cm−2 and afforded an outstanding peak power density of 255 mW cm−2.

Published

2021

5. Stabilizing atomic Pt with trapped interstitial F in alloyed PtCo nanosheets for high-performance zinc-air batteries

Author

Marcos Lucero, Manasi V. Vyas, Nusaiba Zaman, Zhao Li, Hui Cao, Yang Yang, Widitha Samarakoon, Wenhan Niu, Zhenzhong Yang, George E. Sterbinsky, Zhenxing Feng, Abdelkader Kara, Hua Zhou, Yingge Du, and Maoyu Wang

Subjects

Materials science, Renewable Energy, Sustainability and the Environment, Lattice distortion, chemistry.chemical_element, Zinc, Pollution, Oxygen reduction, Catalysis, Nuclear Energy and Engineering, chemistry, Chemical engineering, Fluorine, Environmental Chemistry, Platinum, Cobalt, Power density

Abstract

Recently, considerable attention has been paid to the stabilization of atomic platinum (Pt) catalysts on desirable supports in order to reduce Pt consumption, improve the catalyst stability, and thereafter enhance the catalyst performance in renewable energy devices such as fuel cells and zinc-air batteries (ZABs). Herein, we rationally designed a novel strategy to stabilize atomic Pt catalysts in alloyed platinum cobalt (PtCo) nanosheets with trapped interstitial fluorine (SA-PtCoF) for ZABs. The trapped interstitial F atoms in the PtCoF matrix induce lattice distortion resulting in weakening of the Pt–Co bond, which is the driving force to form atomic Pt. As a result, the onset potentials of SA-PtCoF are 0.95 V and 1.50 V for the oxygen reduction and evolution reactions (ORR and OER), respectively, superior to commercial Pt/C@RuO2. When used in ZABs, the designed SA-PtCoF can afford a peak power density of 125 mW cm−2 with a specific capacity of 808 mA h gZn−1 and excellent cyclability over 240 h, surpassing the state-of-the-art catalysts.

Published

2020

6. Methanol tolerance of atomically dispersed single metal site catalysts: mechanistic understanding and high-performance direct methanol fuel cells

Author

Gang Wu, Macros Lucero, Zhenxing Feng, Yuanyue Liu, Xunhua Zhao, David A. Cullen, Maoyu Wang, Qiurong Shi, Karren L. More, Yanghua He, Xiaowan Bai, and Hua Zhou

Subjects

Materials science, 02 engineering and technology, Electrolyte, 010402 general chemistry, 01 natural sciences, 7. Clean energy, Catalysis, Metal, chemistry.chemical_compound, Adsorption, Environmental Chemistry, Methanol fuel, Renewable Energy, Sustainability and the Environment, 021001 nanoscience & nanotechnology, Pollution, 0104 chemical sciences, Membrane, Nuclear Energy and Engineering, Chemical engineering, chemistry, 13. Climate action, Standard electrode potential, visual_art, visual_art.visual_art_medium, Methanol, 0210 nano-technology

Abstract

Proton-exchange membrane fuel cells (PEMFCs) and direct methanol fuel cells (DMFCs) are promising power sources from portable electronic devices to vehicles. The high-cost issue of these low-temperature fuel cells can be primarily addressed by using platinum-group metal (PGM)-free oxygen reduction reaction (ORR) catalysts, in particular atomically dispersed metal–nitrogen–carbon (M–N–C, M = Fe, Co, Mn). Furthermore, a significant advantage of M–N–C catalysts is their superior methanol tolerance over Pt, which can mitigate the methanol cross-over effect and offer great potential of using a higher concentration of methanol in DMFCs. Here, we investigated the ORR catalytic properties of M–N–C catalysts in methanol-containing acidic electrolytes via experiments and density functional theory (DFT) calculations. FeN4 sites demonstrated the highest methanol tolerance ability when compared to metal-free pyridinic N, CoN4, and MnN4 active sites. The methanol adsorption on MN4 sites is even strengthened when electrode potentials are applied during the ORR. The negative influence of methanol adsorption becomes significant for methanol concentrations higher than 2.0 M. However, the methanol adsorption does not affect the 4e− ORR pathway or chemically destroy the FeN4 sites. The understanding of the methanol-induced ORR activity loss guides the design of promising M–N–C cathode catalyst in DMFCs. Accordingly, we developed a dual-metal site Fe/Co–N–C catalyst through a combined chemical-doping and adsorption strategy. Instead of generating a possible synergistic effect, the introduced Co atoms in the first doping step act as “scissors” for Zn removal in metal–organic frameworks (MOFs), which is crucial for modifying the porosity of the catalyst and providing more defects for stabilizing the active FeN4 sites generated in the second adsorption step. The Fe/Co–N–C catalyst significantly improved the ORR catalytic activity and delivered remarkably enhanced peak power densities (i.e., 502 and 135 mW cm−2) under H2–air and methanol–air conditions, respectively, representing the best performance for both types of fuel cells. Notably, the fundamental understanding of methanol tolerance, along with the encouraging DMFC performance, will open an avenue for the potential application of atomically dispersed M–N–C catalysts in other direct alcohol or ammonia fuel cells.

Published

2020

7. Boosting alkaline hydrogen evolution: the dominating role of interior modification in surface electrocatalysis

Author

Zhenxing Feng, Wenhan Niu, Qi Wang, Yang Yang, Yingge Du, Abdelkader Kara, Maoyu Wang, Zhenzhong Yang, Meng Gu, and Zhao Li

Subjects

Materials science, Electrolysis of water, Renewable Energy, Sustainability and the Environment, Electrochemical kinetics, Electrocatalyst, Pollution, Dissociation (chemistry), Catalysis, Chemical state, Nuclear Energy and Engineering, Chemical engineering, Hydrogen fuel, Environmental Chemistry, Surface modification

Abstract

The alkaline hydrogen evolution reaction (A-HER) holds great promise for clean hydrogen fuel generation but its practical utilization is severely hindered by the sluggish kinetics for water dissociation in alkaline solutions. Traditional ways to improve the electrochemical kinetics for A-HER catalysts have been focusing on surface modification, which still can not meet the demanding requirements for practical water electrolysis because of catalyst surface deactivation. Herein, we report an interior modification strategy to significantly boost the A-HER performance. Specifically, a trace amount of Pt was doped in the interior Co2P (Pt–Co2P) to introduce a stronger dopant–host interaction than that of the surface-modified catalyst. Consequently, the local chemical state and electronic structure of the catalysts were adjusted to improve the electron mobility and reduce the energy barriers for hydrogen adsorption and H–H bond formation. As a proof-of-concept, the interior-modified Pt–Co2P shows a reduced onset potential at near-zero volts for the A-HER, low overpotentials of 2 mV and 58 mV to achieve 10 and 100 mA cm−2, and excellent durability for long-term utilization. The interior-modified Pt–Co2P delivers superior A-HER performance to Pt/C and other state-of-the-art electrocatalysts. This work will open a new avenue for A-HER catalyst design.

Published

2020

8. The role of titanium-oxo clusters in the sulfate process for TiO2 production

Author

May Nyman, Nicolas P. Martin, Pedro I. Molina, Maoyu Wang, Karoly Kozma, and Zhenxing Feng

Subjects

chemistry.chemical_classification, Materials science, Aqueous solution, 010405 organic chemistry, Salt (chemistry), chemistry.chemical_element, Sulfuric acid, engineering.material, 010402 general chemistry, 01 natural sciences, 0104 chemical sciences, Inorganic Chemistry, chemistry.chemical_compound, Crystallography, chemistry, engineering, Sulfate, Absorption (chemistry), Dissolution, Ilmenite, Titanium

Abstract

TiO2 is manufactured for white pigments, solar cells, self-cleaning surfaces and devices, and other photocatalytic applications. The industrial synthesis of TiO2 entails: (1) the dissolution of ilmenite ore (FeTiO3) in aqueous sulfuric acid which precipitates the Fe while retaining the Ti in solution, followed by (2) dilution or heating the Ti sulfate solution to precipitate the pure form of TiO2. The underlying chemistry of these processing steps remains poorly understood. Here we show that the dissolution of a simple TiIV-sulfate salt, representative of the industrial sulfate process for the production of TiO2, immediately self-assembles into a soluble Ti-octadecameric cluster, denoted as {Ti18}. We observed {Ti18} in solution by small-angle X-ray scattering and Ti extended X-ray absorption fine structure (Ti-EXAFS) analysis, and ultimately crystallized it for absolute identification. The {Ti18} metal-oxo cluster was previously reported as a polycation; but shown here, it can also be a polyanion, dependent on the number of sulfate ligands it carries. After immediate self-assembly, the {Ti18}-cluster persists until TiO2 precipitates, with no easily identified structural intermediates in the solution or solid state, despite the fact that the atomic arrangement of {Ti18} differs vastly from that of titania. The evolution from solution phase {Ti18} to precipitated TiO2 nanoparticles was detailed by X-ray scattering and Ti-EXAFS. We offer a hypothesis for the key mechanism of complete separation of Fe from Ti in the industrial sulfate process. These findings also highlight the emerging importance of the unusual Ti(Ti)5 pentagonal building unit, featured in {Ti18} as well as other early d0 transition metal-oxo clusters including Nb, Mo and W. Finally, this study presents an example of crystal growth mechanisms in which the observed “pre-nucleation cluster” does not necessarily predicate the structure of the precipitated solid.

Published

2019

9. 3D porous graphitic nanocarbon for enhancing the performance and durability of Pt catalysts: a balance between graphitization and hierarchical porosity

Author

Yanghua He, Zhenxing Feng, Zhi Qiao, Mengjie Chen, Jacob S. Spendelow, Maoyu Wang, Widitha Samarakoon, Guofeng Wang, Chenyu Wang, Dong Su, Dongguo Li, Sooyeon Hwang, Hua Zhou, Stavros Karakalos, Zhenyu Liu, Xing Li, and Gang Wu

Subjects

chemistry.chemical_classification, Materials science, Renewable Energy, Sustainability and the Environment, Carbonization, Proton exchange membrane fuel cell, chemistry.chemical_element, 02 engineering and technology, Polymer, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Pollution, 0104 chemical sciences, Corrosion, Catalysis, Nuclear Energy and Engineering, chemistry, Chemical engineering, Environmental Chemistry, 0210 nano-technology, Porosity, Pyrolysis, Carbon

Abstract

Carbon supports used in oxygen-reduction cathode catalysts for proton exchange membrane fuel cells (PEMFCs) are vulnerable to corrosion under harsh operating conditions, leading to poor performance durability. To address this issue, we have developed highly stable porous graphitic carbon (PGC) produced through pyrolysis of a 3D polymer hydrogel in combination with Mn. The resulting PGC features multilayer carbon sheets assembled in porous and flower-like morphologies. In situ high-temperature electron microscopy was employed to dynamically monitor the carbonization process up to 1100 °C, suggesting that the 3D polymer hydrogel provides high porosity at multiple scales, and that Mn catalyzes the graphitization process more effectively than other metals. Compared to conventional carbon supports such as Vulcan, Ketjenblack, and graphitized carbon, PGC provides an improved balance between high graphitization and hierarchical porosity, which is favorable for uniform Pt nanoparticle dispersion and enhanced corrosion resistance. As a result, Pt supported on PGC exhibits remarkably enhanced stability. In addition to thorough testing in aqueous electrolytes, we also conducted fuel cell testing using durability protocols recommended by the U.S. Department of Energy (DOE). After 5000 voltage cycles from 1.0 to 1.5 V, the Pt/PGC catalyst only lost 9 mV at a current density of 1.5 A cm−2, dramatically exceeding the DOE support durability target (

Published

2019