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1. Tuning the Solvation Structure in Water‐Based Solution Enables Surface Reconstruction of Layered Oxide Cathodes toward Long Lifespan Sodium‐Ion Batteries

Author

Youchen Hao, Yufan Xia, Wen Liu, Guojie Sun, Lihua Feng, Xiaochong Zhou, Sikandar Iqbal, Ziqi Tian, Zhongcai Zhang, Yong Li, Xuan Zhang, and Yinzhu Jiang

Subjects
layered oxides, sodium‐ion batteries, solvation tuning strategy, surface reconstruction, water‐based solution, Science
Abstract

Abstract Layered oxides of sodium‐ion batteries suffer from severe side reactions on the electrode/electrolyte interface, leading to fast capacity degradation. Although surface reconstruction strategies are widely used to solve the above issues, the utilization of the low‐cost wet chemical method is extremely challenging for moisture‐sensitive Na‐based oxide materials. Here, the solvation tuning strategy is proposed to overcome the deterioration of NaNi1/3Mn1/3Fe1/3O2 in water‐based solution and conduct the surface reconstruction. When capturing the water molecules by the solvation structure of cations, here is Li+, the structural collapse and degradation of layered oxides in water‐based solvents are greatly mitigated. Furthermore, Li(H2O)3EA+ promotes the profitable Li+/Na+ exchange to build a robust surface, which hampers the decomposition of electrolytes and the structural evolution upon cycling. Accordingly, the lifespan of Li‐reinforced materials is prolonged to three times that of the pristine one. This work represents a step forward in understanding the surface reconstruction operated in a water‐based solution for high‐performance sodium layered oxide cathodes.

Published
2024
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2. Revitalizing sodium-ion batteries via controllable microstructures and advanced electrolytes for hard carbon

Author

Feng Wang, Zhenming Jiang, Yanyan Zhang, Yanlei Zhang, Jidao Li, Huibo Wang, Yinzhu Jiang, Guichuan Xing, Hongchao Liu, and Yuxin Tang

Subjects
Hard carbon, Coulombic efficiency, Controllable microstructure, Electrolyte regulation, Sodium storage mechanism, Sodium-ion batteries, Mechanical engineering and machinery, TJ1-1570, Electronics, TK7800-8360
Abstract

Sodium-ion batteries (SIBs) with low cost and high safety are considered as an electrochemical energy storage technology suitable for large-scale energy storage. Hard carbon, which is inexpensive and has both high capacity and low sodium storage potential, is regarded as the most promising anode for commercial SIBs. However, the commercialization of hard carbon still faces technical issues of low initial Coulombic efficiency, poor rate performance, and insufficient cycling stability, due to the intrinsically irregular microstructure of hard carbon. To address these challenges, the rational design of the hard carbon microstructure is crucial for achieving high-performance SIBs, via gaining an in-depth understanding of its structure–performance correlations. In this context, our review firstly describes the sodium storage mechanism from the perspective of the hard carbon microstructure's formation. We then summarize the state-of-art development of hard carbon, providing a critical overview of emergence of hard carbon in terms of precursor selection, microstructure design, and electrolyte regulation to optimize strategies for addressing practical problems. Finally, we highlight directions for the future development of hard carbon to achieve the commercialization of high-performance SIBs. We believe this review will serve as basic guidance for the rational design of hard carbon and stimulate more exciting research into other types of energy storage devices.

Published
2024
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3. Boosting the performance of aqueous zinc‐ion battery by regulating the electrolyte solvation structure

Author

Xingxing Wu, Yufan Xia, Shuang Chen, Zhen Luo, Xuan Zhang, Muhammad Wakil Shahzad, Ben Bin Xu, Hongge Pan, Mi Yan, and Yinzhu Jiang

Subjects
electrolyte additive, solvation structure, zinc‐ion batteries, Zn plating/stripping, Renewable energy sources, TJ807-830, Environmental sciences, GE1-350
Abstract

Abstract The practical implementation of aqueous Zn‐ion batteries (ZIBs) for large‐scale energy storage is impeded by the challenges of water‐induced parasitic reactions and uncontrolled dendrite growth. Herein, we propose a strategy to regulate both anions and cations of electrolyte solvation structures to address above challenges, by introducing an electrolyte additive of 3‐hydroxy‐4‐(trimethylammonio)butyrate (HTMAB) into ZnSO4 electrolyte. Consequently, the deposition of Zn is significantly improved leading to a highly reversible Zn anode with paralleled texture. The Zn/Zn cells with ZnSO4/HTMAB exhibit outstanding cycling performance, showcasing a lifespan exceeding 7500 h and an exceptionally high accumulative capacity of 16.47 Ah cm−2. Zn/NaV3O8·1.5H2O full cell displays a specific capacity of ~130 mAh g−1 at 5 A g−1 maintaining a capacity retention of 93% after 2000 cycles. This work highlights the regulation on both cations and anions of electrolyte solvation structures in optimizing interfacial stability during Zn plating/stripping for high performance ZIBs.

Published
2024
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4. Synergistic 'Anchor-Capture' Enabled by Amino and Carboxyl for Constructing Robust Interface of Zn Anode

Author

Zhen Luo, Yufan Xia, Shuang Chen, Xingxing Wu, Ran Zeng, Xuan Zhang, Hongge Pan, Mi Yan, Tingting Shi, Kai Tao, Ben Bin Xu, and Yinzhu Jiang

Subjects
Zn anode–electrolyte interface, Polar groups, Synergistic “anchor-capture” effect, Side reactions, Dendrite growth, Technology
Abstract

Highlights The synergistic “anchor-capture” mechanism of polar groups on Zn stripping/plating process is firstly proposed. The amino group firmly anchors on Zn surface and the carboxyl group strongly captures Zn2+, constructing a robust anode–electrolyte interface and inducing uniform Zn deposition. The ultra-stable cycle lifespan of Zn–Zn symmetric cell (over 2800 h) and high utilization rate of Zn anode (the depth of discharge up to 68% for 200 h) are achieved under the proposal of synergistic “anchor-capture.”

Published
2023
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5. Reversible Magnesium Metal Anode Enabled by Cooperative Solvation/Surface Engineering in Carbonate Electrolytes

Author

Caiyun Wang, Yao Huang, Yunhao Lu, Hongge Pan, Ben Bin Xu, Wenping Sun, Mi Yan, and Yinzhu Jiang

Subjects
Rechargeable magnesium batteries, Metal anode, Solvation effect, Passivation, Carbonate electrolytes, Technology
Abstract

Abstract Magnesium metal anode holds great potentials toward future high energy and safe rechargeable magnesium battery technology due to its divalent redox and dendrite-free nature. Electrolytes based on Lewis acid chemistry enable the reversible Mg plating/stripping, while they fail to match most cathode materials toward high-voltage magnesium batteries. Herein, reversible Mg plating/stripping is achieved in conventional carbonate electrolytes enabled by the cooperative solvation/surface engineering. Strongly electronegative Cl from the MgCl2 additive of electrolyte impairs the Mg…O = C interaction to reduce the Mg2+ desolvation barrier for accelerated redox kinetics, while the Mg2+-conducting polymer coating on the Mg surface ensures the facile Mg2+ migration and the effective isolation of electrolytes. As a result, reversible plating and stripping of Mg is demonstrated with a low overpotential of 0.7 V up to 2000 cycles. Moreover, benefitting from the wide electrochemical window of carbonate electrolytes, high-voltage (> 2.0 V) rechargeable magnesium batteries are achieved through assembling the electrode couple of Mg metal anode and Prussian blue-based cathodes. The present work provides a cooperative engineering strategy to promote the application of magnesium anode in carbonate electrolytes toward high energy rechargeable batteries.

Published
2021
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6. Porous Bilayer Electrode‐Guided Gas Diffusion for Enhanced CO2 Electrochemical Reduction

Author

Yucheng Wang, Hanhui Lei, Hang Xiang, Yongqing Fu, Chenxi Xu, Yinzhu Jiang, Ben Bin Xu, Eileen Hao Yu, Chao Gao, and Terence Xiaoteng Liu

Subjects
CO2 reduction reaction, gas diffusion electrodes, graphene aerogels, mass transfer, Environmental technology. Sanitary engineering, TD1-1066, Renewable energy sources, TJ807-830
Abstract

Comparing with the massive efforts in developing innovative catalyst materials system and technologies, structural design of cells has attracted less attention on the road toward high‐performance electrochemical CO2 reduction reaction (eCO2RR). Herein, a hybrid gas diffusion electrode‐based reaction cell is proposed using highly porous carbon paper (CP) and graphene aerogels (GAs), which is expected to offer directional diffusion of gas molecules onto the catalyst bed, to sustain a high performance in CO2 conversion. The above‐mentioned hypothesis is supported by the experimental and simulation results, which show that the CP + GA combined configuration increases the Faraday efficiency (FE) from ≈60% to over 94% toward carbon monoxide (CO) and formate production compared with a CP only cell with Cu2O as the catalyst. It also suppresses the undesirable side reaction–hydrogen evolution over 65 times than the conventional H‐type cell (H‐cell). By combining with advanced catalysts with high selectivity, a 100% FE of the cell with a high current density can be realized. The described strategy sheds an extra light on future development of eCO2RR with a structural design of cell‐enabled high CO2 conversion.

Published
2021
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7. An approach through steam to form sulfur nanoparticles for lithium sulfur batteries

Author

Yong Li, Changping Yao, Caiyun Wang, Peng Yang, Ronghui Wu, Linfeng Fei, Yongyi Zhang, and Yinzhu Jiang

Subjects
Lithium sulfur batteries, Sulfur nanoparticles, High-rate performance, Graphene, Steam, Industrial electrochemistry, TP250-261, Chemistry, QD1-999
Abstract

Although tremendous progress has been made in preparing sulfur nanoparticles to achieve high-rate lithium sulfur (Li-S) batteries, the synthetic methods involved are usually toxic, complicated and costly. To solve the above problem, a simple and green method through high pressure steam is developed to prepare sulfur nanoparticles (

Published
2021
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8. Prussian Blue Analogs for Rechargeable Batteries

Author

Baoqi Wang, Yu Han, Xiao Wang, Naoufal Bahlawane, Hongge Pan, Mi Yan, and Yinzhu Jiang

Subjects
Science
Abstract

Summary: Non-lithium energy storage devices, especially sodium ion batteries, are drawing attention due to insufficient and uneven distribution of lithium resources. Prussian blue and its analogs (Prussian blue analogs [PBAs]), or hexacyanoferrates, are well-known since the 18th century and have been used for hydrogen storage, cancer therapy, biosensing, seawater desalination, and sewage treatment. Owing to their unique features, PBAs are receiving increasing interest in the field of energy storage, such as their high theoretical specific capacity, ease of synthesis, as well as low cost. In this review, a general summary and evaluation of the applications of PBAs for rechargeable batteries are given. After a brief review of the history of PBAs, their crystal structure, nomenclature, synthesis, and working principle in rechargeable batteries are discussed. Then, previous works classified based on the combination of insertion cations and transition metals are analyzed comprehensively. The review includes an outlook toward the further development of PBAs in electrochemical energy storage. : Organometallic Chemistry; Electrochemical Energy Storage; Energy Materials Subject Areas: Organometallic Chemistry, Electrochemical Energy Storage, Energy Materials

Published
2018
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14. Amorphous MOFs layer boosts the performance of metal anodes

Author

Yang Xiang, liyuan Zhou, pingping tan, Shuai Dai, Yannan Wang, Shu-Juan Bao, Yinzhu Jiang, Yingying Lu, Maowen Xu, and Xuan Zhang

Abstract

Employing metal anodes can greatly increase volumetric/gravimetric energy density versus a conventional ion-insertion anode. However, metal anodes are plagued by dendrites, corrosion, and interfacial side reactions issues. Herein, a compact and flexible amorphous MOF layer was successfully synthesized and used as protective layer on metal anode aqueous zinc-ion battery (AZIB). Compared with the crystalline MOF layer, the unique amorphous MOF layer can inhibit dendrite growth at the grain boundary and eliminate ions migration near the grain boundary, showing high interfacial adhesion and large ion migration number (tZn2+ = 0.82). Besides, the amorphous MOF layer can effectively depress unfavored behaviors, e.g., corrosion of zinc anode, hydrogen evolution reaction, and dendrite growth on zinc surface. The prepared Zn anode with the amorphous MOF layer exhibited an ultra-long cycle life (ten months, 7000 h) and a low voltage (< 40 mV) at 1 mA cm-2 in a symmetrical cell. Even at 10 mA cm-2, it still showed a high stability for more than 5500 cycles (1200 h). The enhanced performance is realized for full cells paired with a MnO2 cathode. Besides, a flexible symmetrical battery with the Zn@A-ZIF-8 anode exhibited a good cyclability under different bending angle (0°, 90°, and 180°). Moreover, various metal substrates were successfully coated with compact A-ZIF-8. The A-ZIF-8 layer can obviously improve the stability metal anodes, including Zn, Mg and Al. The results not only demonstrate the high potential of amorphous MOFs decorated Zn anodes for AZIBs, but also propose a new family of protective layers for metal anodes.

Published
2023

17. Subtly manipulating Zn2+-coordinated configurations with a complexing agent to boost the reversibility of the zinc anode

Author

Jingjing Xiang, Minghe Luo, Xingxing Wu, Yaofeng Zhu, Xuan Zhang, Hongge Pan, Wenping Sun, Mi Yan, Yingying Lu, and Yinzhu Jiang

Subjects
Materials Chemistry, Metals and Alloys, Ceramics and Composites, General Chemistry, Catalysis, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials
Abstract

By manipulating the Zn2+ coordination environment, electrolytes with diverse Zn2+–En configurations effectively inhibit zinc dendrite growth and side reactions.

Published
2022

18. Achieving Efficient Electrocatalytic Oxygen Evolution in Acidic Media on Yttrium Ruthenate Pyrochlore through Cobalt Incorporation

Author

Ning Han, Shihui Feng, Yi Liang, Jun Wang, Wei Zhang, Xiaolong Guo, Qianru Ma, Qiong Liu, Wei Guo, Zhenyu Zhou, Sijie Xie, Kai Wan, Yinzhu Jiang, Alexandru Vlad, Yuzheng Guo, Eric M. Gaigneaux, Chi Zhang, Jan Fransaer, and Xuan Zhang

Subjects
Biomaterials, Electrochemistry, Condensed Matter Physics, Electronic, Optical and Magnetic Materials
Published
2023

21. Contributors

Author

Takeshi Akinaga, Fadi Alnaimat, S. Arulvel, Gil Azinheira, Christian Breyer, Upeksha Caldera, Mário Costa, Laurent Dala, P.A. Davies, Agustín M. Delgado-Torres, D. Dsilva Winfred Rufuss, Robert W. Field, Daniele Ganora, Lourdes García-Rodríguez, Veera Gnaneswar Gude, Hamdy Hassan, Ahmed Ishag, Yinzhu Jiang, V. Kapoor, Bassam Khuwaileh, Kim Choon Ng, Alberto Pistocchi, Yasir Rashid, Raquel Segurado, Muhammad Wakil Shahzad, Guoying Wei, Ben Bin Xu, and Mohamed S. Yousef

Published
2023

23. Fast and Durable Alkaline Hydrogen Oxidation Reaction at Electron-Deficient Ruthenium-Ruthenium Oxide Interface

Author

Xiaoyu (Baohua) Zhang, Lixue Xia, Guoqiang Zhao, Bingxing Zhang, Yaping Chen, Jian Chen, Mingxia Gao, Yinzhu Jiang, Yongfeng Liu, Hongge Pan, and Wenping Sun

Subjects
Mechanics of Materials, Mechanical Engineering, General Materials Science
Abstract

The slow hydrogen oxidation reaction (HOR) kinetics under alkaline conditions remains a critical challenge for the practical application of alkaline exchange membrane fuel cells. Herein, we design Ru/RuO

Published
2022

24. A Novel Tin-Bonded Silicon Anode for Lithium-Ion Batteries

Author

Mingxia Gao, Chenhui Yan, Yinzhu Jiang, Gairong Chen, Wenping Sun, Chenyang Zhang, Hongge Pan, Yaxiong Yang, Jian Chen, Wubin Du, Jiantuo Gan, Yongfeng Liu, and Zhe Dong

Subjects
Materials science, Silicon, chemistry, Electrode, chemistry.chemical_element, General Materials Science, Conductivity, Composite material, Polarization (electrochemistry), Tin, Faraday efficiency, Anode, Dielectric spectroscopy
Abstract

Poor cyclic stability and low rate performance due to dramatic volume change and low intrinsic electronic conductivity are the two key issues needing to be urgently solved in silicon (Si)-based anodes for lithium-ion batteries. Herein, a novel tin (Sn)-bonded Si anode is proposed for the first time. Sn, which has a high electronic conductivity, is used to bond the Si-anode material and copper (Cu) current collector together using a hot-pressed method with a temperature slightly above the melting point of Sn. The cycling performance of the electrode is studied using a galvanostatic method. Nanoindentation and peeling tests are conducted to measure the mechanical strength of the electrodes. Direct current polarization and galvanostatic intermittent titration techniques are applied to assess the conductivity of the composites. Electrochemical impedance spectroscopy and X-ray photoelectron spectroscopy are conducted to evaluate the effect of the coating layer on the cycling ability of the composites. The Sn-bonded Si anodes show superior cycling stability and high rate performance with an improved initial Coulombic efficiency. Analyses reveal that the low-melting-point Sn helps to markedly improve the electronic conductivity of the electrodes and serves as a metallic binder as well to enhance the adhesive strength of the electrode. It is hopeful that this novel Sn-bonded Si anode provides a new insight for the development of advanced Si-based anodes for LIBs.

Published
2021

25. Performance Evaluation of Desalination Technologies at Common Energy Platform

Author

Wakil, Shahzad, Muhammad, Choon, Ng, Kim, Muhammad, Burhan, Chen, Qian, Doskhan, Ybyraiykul, M., Kumja, Ahmad, Jamil, Muhammad, Yinzhu, Jiang, Nida, Imtiaz, and Bin, Xu, Ben

Abstract

A major fraction of secondary energy consumed for our daily activities, such as electricity and low-grade heat sources, emanates from the conversion of fossil fuels in power plants. In the seawater desalination processes, the energy efficiency is usually expressed in kWh electricity or kWh of low-grade heat per unit volume of water produced. Although kWh energy unit provides a quantitative measure of input energy, it has subtly omitted the embedded quality of supplied energy to desalination plants. In assuming the equivalency across dissimilar energy forms, it results in a thermodynamic misconception that has eluded the desalination industry hitherto, i.e., not all units of derived energy are created equal. An incomplete energy efficacy approach may result in the inferior selection of desalination processes to be deployed;—a phenomenon observed in the trend of installed desalination capacity globally. Operating a less efficient desalination plant over its lifespan would create much economic burdens including a higher unit cost of water, higher CO2 emissions and greater brine discharge to the environment. This book chapter clarifies the key concept and a thermodynamic framework to rectify the misconception in energy consumption, permitting energy planners and designers to optimize deployment of future desalination plants for energy sustainability. We have derived conversion factors to convert assorted derived energies into standard primary energy for fair comparison.

Published
2022

26. Beyond Lithium: A New Era of Sustainable Energy Engineering

Author

Ben Bin Xu, Yinzhu Jiang, Terence Xiaoteng Liu, Zaiping Guo, Guihua Yu, and Maria‐Magdalena Titirici

Subjects
Biomaterials, Electric Power Supplies, General Materials Science, H800, General Chemistry, Renewable Energy, Lithium, Biotechnology
Published
2022

27. Towards defect-free Prussian blue-based battery electrodes

Author

Yuting Gao, Yao Huang, Hongge Pan, Lei Ji, Li Wang, Yuxin Tang, Yaofeng Zhu, Mi Yan, Guoxing Sun, Wenbin Ni, and Yinzhu Jiang

Subjects
Mechanics of Materials, Mechanical Engineering, Materials Chemistry, Metals and Alloys
Published
2023

29. One-Step Reductive Electrodeposition of MOF Film on Polymer Membrane

Author

Sijie Xie, Xuan Zhang, Xiaoyu Tan, Wei Zhang, Wei Guo, Ning Han, Zhenyu Zhou, Yinzhu Jiang, Ivo F. J. Vankelecom, and Jan Fransaer

Subjects
Technology, METAL-ORGANIC FRAMEWORKS, CONVERSION, Science & Technology, General Chemical Engineering, Materials Science, Biomedical Engineering, General Materials Science, Materials Science, Multidisciplinary, ELECTROCHEMICAL DEPOSITION, HOLLOW-FIBER
Abstract

ispartof: ACS MATERIALS LETTERS vol:4 issue:9 pages:1721-1725 status: published

Published
2022

30. Subtly manipulating Zn

Author

Jingjing, Xiang, Minghe, Luo, Xingxing, Wu, Yaofeng, Zhu, Xuan, Zhang, Hongge, Pan, Wenping, Sun, Mi, Yan, Yingying, Lu, and Yinzhu, Jiang

Subjects
Excipients, Zinc, Electrodes
Abstract

By using ethylenediamine (En) as a complexing agent, the impact of various Zn

Published
2022

31. Electrostatically directed assembly of two-dimensional ultrathin Co2Ni-MOF/Ti

Author

Pingping, Tan, Rongwei, Gao, Yawei, Zhang, Ning, Han, Yinzhu, Jiang, Maowen, Xu, Shu-Juan, Bao, and Xuan, Zhang

Abstract

Hydrogen production from water electrolysis is severely restricted by the poor reaction kinetics of oxygen evolution reaction (OER). In this work, a series of two-dimensional (2D) composites MOF/Ti

Published
2022

32. Atomic-Level Modulation of the Interface Chemistry of Platinum–Nickel Oxide toward Enhanced Hydrogen Electrocatalysis Kinetics

Author

Yan Zhao, Yumin Qian, Guoqiang Zhao, Wenping Sun, Yinzhu Jiang, Lixue Xia, Hongge Pan, Shi Xue Dou, and Peixin Cui

Subjects
Hydrogen, Mechanical Engineering, Nickel oxide, Non-blocking I/O, chemistry.chemical_element, Exchange current density, Bioengineering, Heterojunction, 02 engineering and technology, General Chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Electrocatalyst, Electron transfer, chemistry, Chemical engineering, General Materials Science, 0210 nano-technology, Platinum
Abstract

Precise manipulation of the interactions between different components represents the frontier of heterostructured electrocatalysts and is crucial to understanding the structure-function relationship. Current studies, however, are quite limited. Here, we report targeted modulation of the atomic-level interface chemistry of Pt/NiO heterostructure via an annealing treatment, which results in substantially enhanced hydrogen electrocatalysis kinetics in alkaline media. Specifically, the optimized Pt/NiO heterostructure delivers by far the highest specific exchange current density of 8.1 mA cmPt-2 for hydrogen oxidation reaction. X-ray spectroscopy results suggest Pt-Ni interfacial bonds are formed after annealing, inducing more significant electron transfer from NiO to Pt. Also, the regulated interface chemistry, as proven by theoretical calculations, optimizes the binding behaviors of hydrogen and hydroxyl species. These findings emphasize the importance of interface engineering at the atomic level and inspire further explorations of heterostructured electrocatalysts.

Published
2021

34. Interface engineering of heterostructured electrocatalysts towards efficient alkaline hydrogen electrocatalysis

Author

Yinzhu Jiang, Hongge Pan, Wenping Sun, Shi Xue Dou, and Guoqiang Zhao

Subjects
Multidisciplinary, Materials science, Hydrogen, Kinetics, chemistry.chemical_element, Nanotechnology, Reaction intermediate, Hydrogen cycle, 010502 geochemistry & geophysics, Electrocatalyst, Electrochemistry, 01 natural sciences, Redox, Adsorption, chemistry, 0105 earth and related environmental sciences
Abstract

Boosting the alkaline hydrogen evolution and oxidation reaction (HER/HOR) kinetics is vital to practicing the renewable hydrogen cycle in alkaline media. Recently, intensive research has demonstrated that interface engineering is of critical significance for improving the performance of heterostructured electrocatalysts particularly toward the electrochemical reactions involving multiple reaction intermediates like alkaline hydrogen electrocatalysis, and the research advances also bring substantial non-trivial fundamental insights accordingly. Herein, we review the current status of interface engineering with respect to developing efficient heterostructured electrocatalysts for alkaline HER and HOR. Two major subjects—how interface engineering promotes the reaction kinetics and what fundamental insights interface engineering has brought into alkaline HER and HOR—are discussed. Specifically, heterostructured electrocatalysts with abundant interfaces have shown substantially accelerated alkaline hydrogen electrocatalysis kinetics owing to the synergistic effect from different components, which could balance the adsorption/desorption behaviors of the intermediates at the interfaces. Meanwhile, interface engineering can effectively tune the electronic structures of the active sites via electronic interaction, interfacial bonding, and lattice strain, which would appropriately optimize the binding energy of targeted intermediates like hydrogen. Furthermore, the confinement effect is critical for delivering high durability by sustaining high density of active sites. At last, our own perspectives on the challenges and opportunities toward developing efficient heterostructured electrocatalysts for alkaline hydrogen electrocatalysis are provided.

Published
2021

35. Konjac glucomannan biopolymer as a multifunctional binder to build a solid permeable interface on Na3V2(PO4)3/C cathodes for high-performance sodium ion batteries

Author

Xiaoying Zhu, Yinzhu Jiang, Dan Kai, Baoliang Chen, Qingyu Yan, and Yuyao Zhang

Subjects
Materials science, Passivation, Renewable Energy, Sustainability and the Environment, 02 engineering and technology, General Chemistry, Electrolyte, engineering.material, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Redox, Durability, Cathode, 0104 chemical sciences, law.invention, Chemical engineering, law, Electrode, engineering, Specific energy, General Materials Science, Biopolymer, 0210 nano-technology
Abstract

The cathode materials for sodium ion batteries (SIBs) are intrinsically unstable due to their oxidation by electrolyte solution at high voltage; thus, developing novel solid permeable interfaces as passivation layers is critical to avoid these side oxidation reactions and increase the cycling durability of SIBs. Nevertheless, the abuse of passivation layers can hinder the Na+ transfer and further impact the rate capability. Herein, we demonstrated an effective approach that utilized konjac glucomannan (KGM) biopolymer as a multifunctional binder to build stable solid permeable interface films to achieve high-performance for Na3V2(PO4)3/C (NVP) cathodes. Compared with polyvinylidene difluoride (PVDF), the strong adhesion and solid permeable interface films of KGM protect the integrity of the electrodes. The unique conductive network and rich polar functional groups enable KGM to enhance the transfer of electrons and Na+ ions at the interfaces. Thanks to the multiple functions of KGM offering adhesion strength, a conductive network and a solid permeable interface, the NVP cathode exhibited a reversible capacity of 108.0 mA h g−1 at 0.5C (1C = 117 mA g−1). At a high rate of 50C, NVP profited from KGM to show a good capacity of 63.1 mA h g−1 and a high durability of 10 000 cycles with a small fading rate of 0.00259% per cycle. Hard carbon‖NVP full batteries, using KGM as the cathode binder, possessed a high specific energy of 137.7 W h kg−1, indicating the potential applications of KGM as an environmentally friendly binder for achieving high-rate capacity and long-term cycling durability of SIBs.

Published
2021

36. Conformally Anodizing Hierarchical Structure in a Deformed Tube towards Energy-saving Liquid Transportation

Author

Kaiqi Zhao, Ben Bin Xu, Yinzhu Jiang, Muhammad Wakil Shahzad, Jian Jin, Li Wei, Lidong Sun, Xue Chen, Omar Matar, Honghao Zhou, and Sheng Dai

Subjects
Materials science, Anodizing, General Chemical Engineering, 0904 Chemical Engineering, F200, General Chemistry, H800, engineering.material, Chemical Engineering, Industrial and Manufacturing Engineering, Cathode, Superhydrophobic coating, 0905 Civil Engineering, law.invention, Contact angle, 0907 Environmental Engineering, Coating, law, engineering, Environmental Chemistry, Tube (fluid conveyance), Wetting, Composite material, Coaxial
Abstract

The creation of drag-reducing surfaces in deformed tubes is of vital importance to thermal management, energy, and environmental applications. However, it remains a great challenge to tailor the surface structure and wettability inside the deformed tubes of slim and complicated feature. Here, we describe an electrochemical anodization strategy to achieve uniform and superhydrophobic coating of TiO2 nanotube arrays throughout the inner surface in deformed/bend titanium tubes. Guided by a hybrid carbon fibre cathode, conformal electric field can be generated to adaptatively fit the complex geometries in the deformed tube, where the structural design with rigid insulating beads can self-stabilize the hybrid cathode at the coaxial position of the tube with the electrolyte flow. As a result, we obtain a superhydrophobic coating with a water contact angle of 157° and contact angle hysteresis of less than 10°. Substantial drag reduction can be realised with an overall reduction up to 25.8 % for the anodized U-shaped tube. Furthermore, we demonstrate to spatially coat tubes with complex geometries, to achieve energy-saving liquid transportation. This facile coating strategy has great implications in liquid transport processes with the user-friendly approach to engineer surface regardless of the deformation of tube/pipe.

Published
2022

37. Resonance Coupling in an Individual Gold Nanorod–Monolayer WS2 Heterostructure: Photoluminescence Enhancement with Spectral Broadening

Author

Huanjun Chen, Hao Wang, Yinzhu Jiang, Shiya Wen, and Shaozhi Deng

Subjects
Photoluminescence, Materials science, Scattering, business.industry, General Engineering, Physics::Optics, General Physics and Astronomy, Resonance, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Light scattering, 0104 chemical sciences, Condensed Matter::Materials Science, Monolayer, Optoelectronics, General Materials Science, Nanorod, Surface plasmon resonance, 0210 nano-technology, business, Plasmon
Abstract

Recently, resonance coupling between plasmonic nanocavity and two-dimensional semiconductors has attracted considerable attention. Most of the previous studies have focused on demonstrating this effect with light scattering or reflection spectroscopy, while the photoluminescence (PL) spectrum can help ascertain the underlying physics. Here, we report on the light-emitting characteristics of a monolayer WS2 flake coupled with a plasmonic gold nanorod. We construct a heterostructure by integrating an individual gold nanorod on top of a small piece of monolayer WS2, where the WS2 area is determined by the projected area of the nanorod. In such a heterostructure, the background PL from the uncoupled WS2 can be suppressed, which allows us to characterize the resonance coupling effect using correlated single-particle dark-field (DF) scattering and PL spectroscopies. Distinct mode splitting and anticrossing dispersion are observed in the scattering spectra, which originate from the resonance coupling between the excitons in the WS2 and plasmon resonance in the gold nanorod. In addition, a 1187-fold enhancement is obtained for the light emitted from the heterostructure relative to that of the pristine monolayer WS2. The emission spectra are broadened with mode-splitting features at room temperature, which can be further decomposed into two resonance modes using a coupled mode analysis. Moreover, two PL modes are polarized along the longitudinal axis of the gold nanorod. These findings show the potential of the designed individual gold nanorod-monolayer WS2 heterostructure as a platform for studying the resonance coupling effect between plasmon resonance and two-dimensional excitons.

Published
2020

38. Hybrid design of bulk-Na metal anode to minimize cycle-induced interface deterioration of solid Na metal battery

Author

Keshuang Cao, Xitong Zhao, Jian Chen, Ben Bin Xu, Muhammad Wakil Shahzad, Wenping Sun, Hongge Pan, Mi Yan, and Yinzhu Jiang

Subjects
Renewable Energy, Sustainability and the Environment, F200, General Materials Science, H800
Abstract

The pursuit for high-energy and intrinsically safe energy storage is significantly driving the development of solid-state alkali metal batteries. The interfacial contact between the metal anode and the solid electrolyte plays a key role in enabling stable cycling of solid batteries. However, the sluggish alkali atom replenishment rate during stripping unavoidably leads to the interface deterioration that destroys the initial physical contact by forming interfacial voids and triggering the dendrite growth. Herein, a hybrid bulk Na anode approach is proposed by incorporating an ion-conducting phase into a metallic Na matrix, constructing an abundant interfacial electrochemical reaction area and enabling a balanced Na replenishment and consumption to minimize cycle-induced interface deterioration. Specific attention is paid to the effects of the second phase on the wettability and creep ability of hybrid Na metal. A high critical current density (3.1 mA cm-2) and long cycling life (6000 h in 0.5 mA cm-2) are achieved for the symmetric cells. Full cells coupling the hybrid anode with the Na3V2(PO4)3/C cathode deliver excellent cyclability over 7300 cycles at a high rate of 5 C. The viewpoint of balancing the consumption and replenishment rate of metal atoms paves a new way for designing cycle-stable anode/electrolyte interface in solid-state batteries.

Published
2022

39. Visualization of battery materials and their interfaces/interphases using cryogenic electron microscopy

Author

Muhammad Yousaf, Ufra Naseer, Ali Imran, Yiju Li, Waseem Aftab, Asif Mahmood, Nasir Mahmood, Xuan Zhang, Peng Gao, Yingying Lu, Shaojun Guo, Hongge Pan, and Yinzhu Jiang

Subjects
Mechanics of Materials, Mechanical Engineering, General Materials Science, Condensed Matter Physics, Materials, 03 Chemical Sciences, 09 Engineering
Abstract

Future innovations and developments in advanced rechargeable batteries require atomic-scale observation and understanding of the failure mechanisms of secondary batteries. Unfortunately, battery chemistry is highly sensitive to air or moisture and cannot stand electron beam radiation at high dose rates essential for atomic-scale resolution, hence limiting the use of conventional electron or optical microscopes. Recently, cryogenic electron microscopy (cryo-EM) has shown that battery-sensitive materials and interface/interphases can be protected, stabilized, and imaged under cryogenic conditions, facilitating novel insights into key components and phenomena that have a substantial impact on the cell operation. Herein, we highlight the significance and essential role of cryo-EM in characterizing sensitive battery materials (such as Li/Na/K metal anodes, sulfur, lithiated silicon, etc.), key components and interfaces, and summarize the recent contributions and discoveries enabled by cryo-EM. The chemistries and evolving nanostructures at electrode/electrolyte interphase in various electrolytes (both solid and liquid), hosts, artificial interphases, and temperature ranges for lithium-based batteries, and beyond are discussed in detail. Finally, the conclusions and the perspectives on the future direction of cryo-EM in analyzing the battery materials and interfaces are briefly discussed. We believe that the insights and discoveries obtained from this characterizing tool will provide guidelines for developing energy materials with improved electrochemical performance.

Published
2022

40. A Redox Couple Strategy Enables Long-Cycling Li- and Mn-Rich Layered Oxide Cathodes by Suppressing Oxygen Release

Author

Qinong Shao, Panyu Gao, Chenhui Yan, Mingxi Gao, Wubin Du, Jian Chen, Yaxiong Yang, Jiantuo Gan, Zhijun Wu, Chenyang Zhang, Gairong Chen, Xusheng Zheng, Yue Lin, Yinzhu Jiang, Wenping Sun, Yongfeng Liu, Mingxia Gao, and Hongge Pan

Subjects
Mechanics of Materials, Mechanical Engineering, General Materials Science
Abstract

Li- and Mn-rich layered oxides (LMROs) are considered the most promising cathode candidates for next-generation high-energy lithium-ion batteries. The poor cycling stability and fast voltage fading resulting from oxygen release during charging, however, severely hinders their practical application. Herein, a strategy of introducing an additional redox couple is proposed to eliminate the persistent problem of oxygen release. As a proof of concept, the cycling stability of Li

Published
2021

41. Porous Bilayer Electrode‐Guided Gas Diffusion for Enhanced CO2 Electrochemical Reduction

Author

Eileen Hao Yu, Yinzhu Jiang, Hang Xiang, Ben Bin Xu, Yucheng Wang, Hanhui Lei, Terence Xiaoteng Liu, Chenxi Xu, Yong Qing Fu, and Chao Gao

Subjects
Materials science, Gas diffusion electrode, Bilayer, F200, TJ807-830, General Medicine, H800, Electrochemistry, gas diffusion electrodes, Environmental technology. Sanitary engineering, graphene aerogels, Renewable energy sources, Reduction (complexity), Chemical engineering, Mass transfer, Electrode, mass transfer, Gaseous diffusion, CO2 reduction reaction, Porosity, TD1-1066
Abstract

Comparing with the massive efforts in developing innovative catalyst materials system and technologies, structural design of cells has attracted less attention on the road toward high‐performance electrochemical CO2 reduction reaction (eCO2RR). Herein, a hybrid gas diffusion electrode‐based reaction cell is proposed using highly porous carbon paper (CP) and graphene aerogels (GAs), which is expected to offer directional diffusion of gas molecules onto the catalyst bed, to sustain a high performance in CO2 conversion. The above‐mentioned hypothesis is supported by the experimental and simulation results, which show that the CP + GA combined configuration increases the Faraday efficiency (FE) from ≈60% to over 94% toward carbon monoxide (CO) and formate production compared with a CP only cell with Cu2O as the catalyst. It also suppresses the undesirable side reaction–hydrogen evolution over 65 times than the conventional H‐type cell (H‐cell). By combining with advanced catalysts with high selectivity, a 100% FE of the cell with a high current density can be realized. The described strategy sheds an extra light on future development of eCO2RR with a structural design of cell‐enabled high CO2 conversion.

Published
2021

42. Dendrite-free zinc anode enabled by zinc-chelating chemistry

Author

Mi Yan, Caiyun Wang, Wenping Sun, Ben Bin Xu, Yunhao Lu, Minghe Luo, Hongge Pan, Haotian Lu, and Yinzhu Jiang

Subjects
Battery (electricity), Aqueous solution, Renewable Energy, Sustainability and the Environment, F100, Solvation, F200, Energy Engineering and Power Technology, chemistry.chemical_element, 02 engineering and technology, Zinc, Electrolyte, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Anode, Dendrite (crystal), Solvation shell, Chemical engineering, chemistry, General Materials Science, 0210 nano-technology
Abstract

Rechargeable aqueous Zn-ion battery has been considered as a key complement to the existing battery technologies due to its intrinsic merits such as operational safety and cost saving. However, issues of dendrite growth and accompanied water consumption hinder its further development. In this work, we utilize a chelating agent, 2-Bis(2-hydroxyethyl) amino-2-(hydroxymethyl)-1,3-propanediol (BIS-TRIS), to regulate the solvation sheath structure of Zn2+. Benefiting from such zinc-chelating coordination, Zn2+ 2D diffusion can be restricted and the altered deposition kinetic has contributed to the inhibition of the dendrite growth. In addition, partial substitution of water in solvation shell with chelator can also greatly suppress the competitive hydrogen evolution reaction (HER). Consequently, a stable symmetric Zn cell with lifetime more than 1000 h at a current density of 1 mA cm−2 is achieved. Moreover, the aqueous Zn/MnO2 battery with BIS-TRIS as electrolyte additive delivers an 86% capacity retention after 600 cycles at 500 mA g−1. This zinc-chelating coordination based facile strategy opens a new window for the future development in dendrite-free Zn anode.

Published
2021

43. Reversible Magnesium Metal Anode Enabled by Cooperative Solvation/Surface Engineering in Carbonate Electrolytes

Author

Yao Huang, Ben Bin Xu, Mi Yan, Yunhao Lu, Yinzhu Jiang, Wenping Sun, Hongge Pan, and Caiyun Wang

Subjects
Carbonate electrolytes, Technology, Materials science, Magnesium, chemistry.chemical_element, H900, H800, Electrolyte, Overpotential, Magnesium battery, Redox, Article, Solvation effect, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Anode, Passivation, Chemical engineering, chemistry, Metal anode, Plating, Rechargeable magnesium batteries, Electrical and Electronic Engineering, Electrochemical window
Abstract

Highlights A cooperative solvation/surface engineering approach is reported to achieve the reversible Mg plating/stripping in conventional carbonate electrolytes.Benefitting from the strategy, Mg2+ can easily overcome the reduced desolvation barrier and penetrate the Mg2+-conducting polymer coating, deposited on the Mg metal anode successfully, promoting the application of magnesium anode in carbonate electrolytes toward high-energy rechargeable batteries. Supplementary Information The online version contains supplementary material available at 10.1007/s40820-021-00716-1., Magnesium metal anode holds great potentials toward future high energy and safe rechargeable magnesium battery technology due to its divalent redox and dendrite-free nature. Electrolytes based on Lewis acid chemistry enable the reversible Mg plating/stripping, while they fail to match most cathode materials toward high-voltage magnesium batteries. Herein, reversible Mg plating/stripping is achieved in conventional carbonate electrolytes enabled by the cooperative solvation/surface engineering. Strongly electronegative Cl from the MgCl2 additive of electrolyte impairs the Mg…O = C interaction to reduce the Mg2+ desolvation barrier for accelerated redox kinetics, while the Mg2+-conducting polymer coating on the Mg surface ensures the facile Mg2+ migration and the effective isolation of electrolytes. As a result, reversible plating and stripping of Mg is demonstrated with a low overpotential of 0.7 V up to 2000 cycles. Moreover, benefitting from the wide electrochemical window of carbonate electrolytes, high-voltage (> 2.0 V) rechargeable magnesium batteries are achieved through assembling the electrode couple of Mg metal anode and Prussian blue-based cathodes. The present work provides a cooperative engineering strategy to promote the application of magnesium anode in carbonate electrolytes toward high energy rechargeable batteries. Supplementary Information The online version contains supplementary material available at 10.1007/s40820-021-00716-1.

Published
2021

44. Latticed‐Confined Conversion Chemistry of Battery Electrode

Author

Libin Fang, Haosheng Li, Ben Bin Xu, Jie Ma, Hongge Pan, Qinggang He, Tianlong Zheng, Wenbin Ni, Yue Lin, Yangmu Li, Yue Cao, Chengjun Sun, Mi Yan, Wenping Sun, and Yinzhu Jiang

Subjects
Biomaterials, Electric Power Supplies, Entropy, H300, H900, General Materials Science, General Chemistry, Electrodes, Body Fluids, Biotechnology
Abstract

The electrochemical conversion reaction, usually featured by multiple redox processes and high specific capacity, holds great promise in developing high-energy rechargeable battery technologies. However, the complete structural change accompanied by spontaneous atomic migration and volume variation during the charge/discharge cycle leads to electrode disintegration and performance degradation, therefore severely restricting the application of conventional conversion-type electrodes. Herein, latticed-confined conversion chemistry is proposed, where the "intercalation-like" redox behavior is realized on the electrode with a "conversion-like" high capacity. By delicately formulating the high-entropy compounds, the pristine crystal structure can be preserved by the inert lattice framework, thus enabling an ultra-high initial Coulombic efficiency of 92.5% and a long cycling lifespan over a thousand cycles after the quasistatic charge-discharge cycle. This lattice-confined conversion chemistry unfolds a ubiquitous insight into the localized redox reaction and sheds light on developing high-performance electrodes toward next-generation high-energy rechargeable batteries.

Published
2022

45. Lattice-Confined Ir Clusters on Pd Nanosheets with Charge Redistribution for the Hydrogen Oxidation Reaction under Alkaline Conditions

Author

Mingxia Gao, Baohua Zhang, Hongge Pan, Bingxing Zhang, Yinzhu Jiang, Guoqiang Zhao, Lixue Xia, Wenping Sun, and Tianyi Ma

Subjects
Materials science, Ion exchange, Hydrogen, Mechanical Engineering, Exchange current density, chemistry.chemical_element, Heterojunction, Electrocatalyst, Photochemistry, Nanoclusters, Adsorption, chemistry, Mechanics of Materials, General Materials Science, Redistribution (chemistry)
Abstract

Electrocatalysts with high activity and long-term stability for the hydrogen oxidation reaction (HOR) under alkaline conditions is still a major challenge for anion exchange membrane fuel cells (AEMFCs). Herein, a heterostructured Ir@Pd electrocatalyst with ultrasmall Ir nanoclusters (NCs) epitaxially confined on Pd nanosheets (NSs) for catalyzing the sluggish alkaline HOR is reported. Apparent charge redistribution occurs across the heterointerface, and both experimental and theoretical results suggest that the electrons transfer from Pd to Ir, which consequently greatly weakens the hydrogen binding on Pd. More interestingly, the interfacial epitaxy results in the formation of Ir/IrO2 Janus nanostructures, where the partially oxidized Ir species away from the interface further optimize the hydroxyl adsorption behavior. The unique Ir@Pd heterostructure eventually shows an optimal balance between hydrogen and hydroxyl adsorption, and hence exhibits impressive HOR activity with an exchange current density of up to 7.18 mA cm-2 in 0.1 m KOH solution. In addition, the Ir@Pd electrocatalyst exhibits negligible activity degradation owing to the confinement effect of the unique epitaxial interface.

Published
2021

46. An All‐Prussian‐Blue‐Based Aqueous Sodium‐Ion Battery

Author

Yinzhu Jiang, Mi Yan, Baoqi Wang, Chu Liang, and Xiao Wang

Subjects
Prussian blue, chemistry.chemical_compound, Aqueous solution, Materials science, chemistry, Electrode, Electrochemistry, Sodium-ion battery, Aqueous electrolyte, Catalysis, Nuclear chemistry
Published
2019

47. Si/Ti3SiC2 composite anode with enhanced elastic modulus and high electronic conductivity for lithium-ion batteries

Author

Haitao Gu, Wubin Du, Mingxia Gao, Chenyang Zhang, Gairong Chen, Yongfeng Liu, Zhe Dong, Tiejun Zhu, Yinzhu Jiang, Hongge Pan, Jian Chen, and Zhenhe Feng

Subjects
Materials science, Silicon, Renewable Energy, Sustainability and the Environment, Scanning electron microscope, Energy Engineering and Power Technology, chemistry.chemical_element, 02 engineering and technology, Nanoindentation, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Anode, Dielectric spectroscopy, chemistry, Transmission electron microscopy, Electrode, Electrical and Electronic Engineering, Physical and Theoretical Chemistry, Composite material, 0210 nano-technology, Elastic modulus
Abstract

Large volume changes (∼300%) during cycling and low electronic conductivity of silicon (Si) always lead to the failure of the Si anode for lithium-ion batteries. In this paper, we report a facile method to fabricate Si/Ti3SiC2 composites by one-step sand-milling process. Ti3SiC2 is used as a mechanical strengthening and high conductive matrix for Si-based anode for the first time. X-ray diffraction (XRD), scanning electron microscopy (SEM) and transmission electron microscopy (TEM) are conducted to characterize the structure and morphology of the Si/Ti3SiC2 composites. Capacity and cycling performance are studied by galvanostatic method. Nanoindentation test is performed to measure the elastic modulus and hardness of the electrodes. Electrochemical impedance spectroscopy (EIS) and four-probe electronic conductivity measurement are used to assess the effect of Ti3SiC2 on the electronic conductivity of Si anode. Electrochemical investigations show that both cycling stability and rate performance of Si/Ti3SiC2 anodes are significantly improved comparing with those of the pure Si anode. SEM, nanoindentation and four-probe electronic conductivity measurement results reveal that the Ti3SiC2 can not only significantly enhance the electronic conductivity of the Si/Ti3SiC2 anodes but also maintain the integrity of the electrode during cycling by markedly increasing the elastic modulus and hardness of the electrodes.

Published
2019

48. A Universal Strategy to Fabricate Metal Sulfides@Carbon Fibers As Freestanding and Flexible Anodes for High-Performance Lithium/Sodium Storage

Author

Yinzhu Jiang, Hang Zhu, Chu Liang, Ting Du, Ben Bin Xu, and Mi Yan

Subjects
Materials science, H600, Sodium, Energy Engineering and Power Technology, Future trend, chemistry.chemical_element, Nanotechnology, Flexible electronics, Electrospinning, Anode, Metal, chemistry, Hardware_GENERAL, visual_art, Electrode, Materials Chemistry, Electrochemistry, visual_art.visual_art_medium, Chemical Engineering (miscellaneous), Lithium, Electrical and Electronic Engineering
Abstract

The future trend toward flexible electronics creates a demand for flexible power sources using rechargeable batteries, where freestanding and flexible electrodes are of critical importance. The utilization of high capacity anode materials like metal sulfides in flexible batteries is highly desirable for the miniaturization of electronic devices but is nevertheless very challenging in the fabrication of an electrode that is freestanding and flexible. Herein, a universal electrospinning strategy to fabricate freestanding and flexible metal sulfides@carbon electrodes is proposed based on the formation of chelate complexes between l-cysteine and metal cations. Taking SnS as a model material, flexible fiber electrodes are realized with SnS nanoparticles well embedded in the continuous and interwoven carbon fibers. As freestanding electrodes for lithium and sodium storage, a high capacity, good rate capability, and excellent cycling stability are simultaneously achieved. Such a strategy is also successfully extended to the fabrication of Ni 3S 2/C fibers and Fe 7S 8/C fibers, suggesting the universality in fabricating freestanding and flexible high capacity electrodes.

Published
2019

49. Hetero-interface constructs ion reservoir to enhance conversion reaction kinetics for sodium/lithium storage

Author

Mi Yan, Yinzhu Jiang, Yunhao Lu, Naoufal Bahlawane, Wenhao Guan, Peng Zhou, Wenping Sun, Chu Liang, Libin Fang, and Zhenyun Lan

Subjects
Materials science, Renewable Energy, Sustainability and the Environment, Sodium, Diffusion, Kinetics, Energy Engineering and Power Technology, chemistry.chemical_element, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrochemistry, 01 natural sciences, 0104 chemical sciences, Anode, Ion, Chemical kinetics, chemistry, Chemical engineering, General Materials Science, Lithium, 0210 nano-technology
Abstract

Developing high-capacity electrode materials is most vital to high-energy rechargeable batteries. The conversion reaction-based anode materials deliver substantially higher theoretical capacities in respect to intercalation-based materials. However, the sluggish conversion reaction kinetics is a big obstacle to deliver high practical capacity and rate capability, which is particularly severe for sodium storage. Herein, we implement an interface engineering approach by designing hetero-interfaces to enhance conversion reaction. As a proof of concept, Sb2S3-SnS2 hetero-nanostructures are synthesized and show greatly improved electrochemical performance in terms of specific capacity and rate capability. The DFT calculations reveal that the hetero-interfacial electric field prompts sodium ions pump into the interfaces, which greatly reduces the activation barrier and hence accelerates reaction kinetics. The Sb2S3-SnS2 hetero-interface serves therefore as a “reservoir” and fast diffusion channel for sodium or lithium ions. The obtained results provide important insights into engineering efficient hetero-nanostructures towards fast conversion reaction kinetics for rechargeable batteries.

Published
2019

50. An approach through steam to form sulfur nanoparticles for lithium sulfur batteries

Author

Yinzhu Jiang, Peng Yang, Ronghui Wu, Linfeng Fei, Changping Yao, Yong Li, Yongyi Zhang, and Caiyun Wang

Subjects
inorganic chemicals, Materials science, Lithium sulfur batteries, chemistry.chemical_element, Nanoparticle, 02 engineering and technology, Sulfur nanoparticles, High-rate performance, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Sulfur, 0104 chemical sciences, TP250-261, Steam, Chemistry, chemistry, Chemical engineering, Industrial electrochemistry, High pressure, Electrochemistry, Lithium sulfur, Graphene, 0210 nano-technology, QD1-999
Abstract

Although tremendous progress has been made in preparing sulfur nanoparticles to achieve high-rate lithium sulfur (Li-S) batteries, the synthetic methods involved are usually toxic, complicated and costly. To solve the above problem, a simple and green method through high pressure steam is developed to prepare sulfur nanoparticles (

Published
2021

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