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List of Issues

    2023, Vol. 82, No. 7 Online: 15 July 2023
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    End-cloud collaboration method enables accurate state of health and remaining useful life online estimation in lithium-ion batteries
    Bin Ma, Lisheng Zhang, Hanqing Yu, Bosong Zou, Wentao Wang, Cheng Zhang, Shichun Yang, Xinhua Liu
    2023, 82(7): 1-17.  DOI: 10.1016/j.jechem.2023.02.052
    Abstract ( 32 )   PDF (21383KB) ( 28 )  
    Though the lithium-ion battery is universally applied, the reliability of lithium-ion batteries remains a challenge due to various physicochemical reactions, electrode material degradation, and even thermal runaway. Accurate estimation and prediction of battery health conditions are crucial for battery safety management. In this paper, an end-cloud collaboration method is proposed to approach the track of battery degradation process, integrating end-side empirical model with cloud-side data-driven model. Based on ensemble learning methods, the data-driven model is constructed by three base models to obtain cloud-side highly accurate results. The double exponential decay model is utilized as an empirical model to output highly real-time prediction results. With Kalman filter, the prediction results of end-side empirical model can be periodically updated by highly accurate results of cloud-side data-driven model to obtain highly accurate and real-time results. Subsequently, the whole framework can give an accurate prediction and tracking of battery degradation, with the mean absolute error maintained below 2%. And the execution time on the end side can reach 261 μs. The proposed end-cloud collaboration method has the potential to approach highly accurate and highly real-time estimation for battery health conditions during battery full life cycle in architecture of cyber hierarchy and interactional network.
    Regulation of excitation energy transfer in Sb-alloyed Cs4MnBi2Cl12 perovskites for efficient CO2 photoreduction to CO and water oxidation toward H2O2
    Haiwen Wei, Zhen Li, Honglei Wang, Yang Yang, Pengfei Cheng, Peigeng Han, Ruiling Zhang, Feng Liu, Panwang Zhou, Keli Han
    2023, 82(7): 18-24.  DOI: 10.1016/j.jechem.2023.03.010
    Abstract ( 13 )   PDF (7951KB) ( 14 )  
    Lead (Pb)-free halide perovskites have recently attracted increasing attention as potential catalysts for CO2 photoreduction to CO due to their potential to capture solar energy and drive catalytic reaction. However, issues of the poor charge transfer still remain one of the main obstacles limiting their performance due to the overwhelming radiative and nonradiative charge-carrier recombination losses. Herein, Pb-free Sb-alloyed all-inorganic quadruple perovskite Cs4Mn(Bi1-xSbx)2Cl12 (0 ≤ x ≤ 1) is synthesized as efficient photocatalyst. By Sb alloying, the undesired relaxation of photogenerated electrons from conduction band to emission centers of [MnCl6]4- is greatly suppressed, resulting in a weakened PL emission and enhanced charge transfer for photocatalyst. The ensuing Cs4Mn(Bi1-xSbx)2Cl12 photocatalyst accomplishes efficient conversion of CO2 into CO, accompanied by a surprising production of H2O2, a high value-added product associated with water oxidation. By optimizing Sb3+ concentration, a high CO evolution rate of 35.1 μmol g-1 h-1 is achieved, superior to most other Pb and Pb-free halide perovskites. Our findings provide new insights into the mixed-cation alloying strategies for improved photocatalytic performance of Pb-free perovskites and shed light on the rational design of robust band structure toward efficient energy transfer.
    Solvents incubated π-π stacking in hole transport layer for perovskite-silicon 2-terminal tandem solar cells with 27.21% efficiency
    Qiaoyan Ma, Jufeng Qiu, Yuzhao Yang, Fei Tang, Yilin Zeng, Nanxi Ma, Bohao Yu, Feiping Lu, Chong Liu, Andreas Lambertz, Weiyuan Duan, Kaining Ding, Yaohua Mai
    2023, 82(7): 25-30.  DOI: 10.1016/j.jechem.2023.03.028
    Abstract ( 16 )   PDF (6009KB) ( 15 )  
    Room temperature sputtered inorganic nickel oxide (NiOx) is one of the most promising hole transport layers (HTL) for perovskite-sillion 2-terminal tandem solar cells with the aid of ultrathin and compact organic layers to passivate the surface defects. In this study, the aromatic solvent with different substituent groups was used to regulate the conformation of poly[bis(4-phenyl)(2,4,6-trimethylphenyl)amine] (PTAA) layer. As a result, the single-junction perovskite solar cell (PSC) gained a power conversion efficiency (PCE) of 20.63%, contributing to a 27.21% efficiency for monolithic perovskite/silicon (double-side polished) 2-terminal tandem solar cell, by applying the alkyl aromatic solvent to enhance the π-π stacking of PTAA molecular chains. The tandem solar cell can maintain 95% initial efficiency after aging over 1000 h. This study provides a universal approach for improving the photovoltaic performance of NiOx/polymer-based perovskite/silicon tandem solar cells and other single junction inverted PSCs.
    Unfolding the structure-property relationships of Li2S anchoring on two-dimensional materials with high-throughput calculations and machine learning
    Lujie Jin, Hongshuai Wang, Hao Zhao, Yujin Ji, Youyong Li
    2023, 82(7): 31-39.  DOI: 10.1016/j.jechem.2023.03.004
    Abstract ( 9 )   PDF (6904KB) ( 9 )  
    Lithium-sulfur (Li-S) batteries are notable for their high theoretical energy density, but the ‘shuttle effect' and the limited conversion kinetics of Li-S species can downgrade their actual performance. An essential strategy is to design anchoring materials (AMs) to appropriately adsorb Li-S species. Herein, we propose a new three-procedure protocol, named InfoAd (Informative Adsorption) to evaluate the anchoring of Li2S on two-dimensional (2D) materials and disclose the underlying importance of material features by combining high-throughput calculation workflow and machine learning (ML). In this paradigm, we calculate the anchoring of Li2S on 1255 2D AxBy (B in the VIA/VIIA group) materials and pick out 44 (un)reported nontoxic 2D binary AxBy AMs, in which the importance of the geometric features on the anchoring effect is revealed by ML for the first time. We develop a new Infograph model for crystals to accurately predict whether a material has a moderate binding with Li2S and extend it to all 2D materials. Our InfoAd protocol elucidates the underlying structure-property relationship of Li2S adsorption on 2D materials and provides a general research framework of adsorption-related materials for catalysis and energy/substance storage.
    Reducing dielectric confinement effect in ionic covalent organic nanosheets to promote the visible-light-driven hydrogen evolution
    Guoqing Li, Xiaolong Zhao, Qihong Yue, Ping Fu, Fangpei Ma, Jun Wang, Yu Zhou
    2023, 82(7): 40-46.  DOI: 10.1016/j.jechem.2023.02.047
    Abstract ( 14 )   PDF (6566KB) ( 12 )  
    Ultra-thin two-dimensional (2D) organic semiconductors are promising candidates for photocatalysts because of the short charge diffusion pathway and favorable exposure of active sites plus the versatile architecture. Nonetheless, the inherent dielectric confinement of 2D materials will induce a strong exciton effect hampering the charge separation. Herein, we demonstrated an effective way to reduce the dielectric confinement effect of 2D ionic covalent organic nanosheets (iCONs) by tailoring the functional group via molecular engineering. Three ultra-thin CONs with different functional groups and the same ionic moieties were synthesized through Schiff base condensation between ionic amino monomer triaminoguanidinium chloride (TG) and aldehyde linkers. The integration of the hydroxyl group was found to significantly increase the dielectric constant by enhancing the polarizability of ionic moieties, and thus reduced the dielectric confinement and the corresponding exciton binding energy (Eb). The champion hydroxyl-functional iCON exhibited promoted exciton dissociation and in turn a high photocatalytic hydrogen production rate under visible-light irradiation. This work provided insights into the rationalization of the dielectric confinement effect of low-dimensional photocatalysts.
    Enhanced H2 permeation and CO2 tolerance of self-assembled ceramic-metal-ceramic BZCYYb-Ni-CeO2 hybrid membrane for hydrogen separation
    Jianqiu Zhu, Jingzeng Cui, Yuxuan Zhang, Ze Liu, Chuan Zhou, Susu Bi, Jingyuan Ma, Jing Zhou, Zhiwei Hu, Tao Liu, Zhi Li, Xiangyong Zhao, Jian-Qiang Wang, Linjuan Zhang
    2023, 82(7): 47-55.  DOI: 10.1016/j.jechem.2023.03.027
    Abstract ( 5 )   PDF (8357KB) ( 7 )  
    Perovskite-type mixed protonic-electronic conducting membranes have attracted attention because of their ability to separate and purify hydrogen from a mixture of gases generated by industrial-scale steam reforming based on an ion diffusion mechanism. Exploring cost-effective membrane materials that can achieve both high H2 permeability and strong CO2-tolerant chemical stability has been a major challenge for industrial applications. Herein, we constructed a triple phase (ceramic-metal-ceramic) membrane composed of a perovskite ceramic phase BaZr0.1Ce0.7Y0.1Yb0.1O3-δ (BZCYYb), Ni metal phase and a fluorite ceramic phase CeO2. Under H2 atmosphere, Ni metal in-situ exsolved from the oxide grains, and decorated the grain surface and boundary, thus the electronic conductivity and hydrogen separation performance can be promoted. The BZCYYbNi-CeO2 hybrid membrane achieved an exceptional hydrogen separation performance of 0.53 mL min-1 cm-2 at 800 °C under a 10 vol% H2 atmosphere, surpassing all other perovskite membranes reported to date. Furthermore, the CeO2 phase incorporated into the BZCYYb-Ni effectively improved the CO2-tolerant chemical stability. The BZCYYbNi-CeO2 membrane exhibited outstanding long-term stability for at least 80 h at 700 °C under 10 vol% CO2-10 vol% H2. The success of hybrid membrane construction creates a new direction for simultaneously improving their hydrogen separation performance and CO2 resistance stability.
    Overlooked impact of precursor mixing: Implications in the electrochemical performance of battery electrode materials
    JinHa Shim, Jin Ho Bang
    2023, 82(7): 56-65.  DOI: 10.1016/j.jechem.2023.03.031
    Abstract ( 12 )   PDF (3687KB) ( 9 )  
    Solid-state reactions are an essential part of the synthesis of various cathode materials for lithium-ion batteries (LIBs). Despite the simplicity and effectiveness for mass production, a subtle variation in synthesis conditions can often give rise to unexpectedly different physical properties, significantly affecting the electrochemical performance of electrode materials. However, this aspect has long been overlooked in the LIB community, which should focus on advancement in understanding the influence of synthesis conditions. As solid-state reactions occur only at the interface of precursor materials, maximizing the interfacial contact area between mixed precursor powders is crucial. Mechanical milling and/or mixing are common practices that have been performed in both academia and industry for this purpose. Unlike the common belief that this pre-treatment before calcination would be of great benefit for the preparation of high-performance LIB materials, we revealed in this work that this practice is not always successful for this goal. In our case study of the preparation of LiCoO2, we demonstrated that mechanical mixing—a routinely implemented process for homogeneous mixing of precursors—can be harmful if it is performed without assuring optimal working conditions for mixing. The underlying reasons for this surprising result are elucidated in this work, and we hope that this new insight can help avoid the potential pitfall of routine implementations performed for LIB materials.
    Toward high-efficiency perovskite solar cells with one-dimensional oriented nanostructured electron transport materials
    Yinhua Lv, Bing Cai, Ruihan Yuan, Yihui Wu, Quinn Qiao, Wen-Hua Zhang
    2023, 82(7): 66-87.  DOI: 10.1016/j.jechem.2023.01.066
    Abstract ( 15 )   PDF (25049KB) ( 8 )  
    The unique advantages of one-dimensional (1D) oriented nanostructures in light-trapping and charge-transport make them competitive candidates in photovoltaic (PV) devices. Since the emergence of perovskite solar cells (PSCs), 1D nanostructured electron transport materials (ETMs) have drawn tremendous interest. However, the power conversion efficiencies (PCEs) of these devices have always significantly lagged behind their mesoscopic and planar counterparts. High-efficiency PSCs with 1D ETMs showing efficiency over 22% were just realized in the most recent studies. It yet lacks a comprehensive review covering the development of 1D ETMs and their application in PSCs. We hence timely summarize the advances in 1D ETMs-based solar cells, emphasizing on the fundamental and optimization issues of charge separation and collection ability, and their influence on PV performance. After sketching the classification and requirements for high-efficiency 1D nanostructured solar cells, we highlight the applicability of 1D TiO2 nanostructures in PSCs, including nanotubes, nanorods, nanocones, and nanopyramids, and carefully analyze how the electrostatic field affects cell performance. Other kinds of oriented nanostructures, e.g., ZnO and SnO2 ETMs, are also described. Finally, we discuss the challenges and propose some potential strategies to further boost device performance. This review provides a broad range of valuable work in this fast-developing field, which we hope will stimulate research enthusiasm to push PSCs to an unprecedented level.
    In-situ cation-inserted MnO2 with selective accelerated intercalation of individual H+ or Zn2+ ions in aqueous zinc ion batteries
    Lijin Yan, Baibai Liu, Jiangyu Hao, Yuying Han, Chong Zhu, Fuliang Liu, Xuefeng Zou, Yang Zhou, Bin Xiang
    2023, 82(7): 88-102.  DOI: 10.1016/j.jechem.2023.03.036
    Abstract ( 8 )   PDF (26904KB) ( 5 )  
    The recognized energy storage mechanism of neutral aqueous zinc-manganese batteries is the co-insertion/extrusion of H+ and Zn2+ ions. However, modulating the kinetics of a single H+ or Zn2+ ion is scarce, which can provide meaningful insights into the energy storage mechanism of Zn ion batteries. Herein, a distinctive doubly electric field in-situ induced cationic anchoring of two-dimensional layered MnO2 is successfully constructed to modulate the insertion/extrusion of a single H+ or Zn2+ ion. As a result, regulating the intercalation of different metal ions can precisely achieve the accelerated induction for the individual H+ or Zn2+ ions intercalation/deintercalation. Moreover, the introduction of metal ions stabilizes the lattice distortion and alleviates the irreparable structural collapse, leading to an increase in the H+/Zn2+ storage sites, efficiently diminishing the stagnation of the ordered structure and creating the more open channels, which is conducive to facilitating the diffusion of ions. This work delivers some innovative insights into pre-embedding strategies, and also serves as a precious reference for the cathode development of advanced aqueous batteries.
    The development of machine learning-based remaining useful life prediction for lithium-ion batteries
    Xingjun Li, Dan Yu, Vilsen Søren Byg, Store Daniel Ioan
    2023, 82(7): 103-121.  DOI: 10.1016/j.jechem.2023.03.026
    Abstract ( 9 )   PDF (7885KB) ( 7 )  
    Lithium-ion batteries are the most widely used energy storage devices, for which the accurate prediction of the remaining useful life (RUL) is crucial to their reliable operation and accident prevention. This work thoroughly investigates the developmental trend of RUL prediction with machine learning (ML) algorithms based on the objective screening and statistics of related papers over the past decade to analyze the research core and find future improvement directions. The possibility of extending lithium-ion battery lifetime using RUL prediction results is also explored in this paper. The ten most used ML algorithms for RUL prediction are first identified in 380 relevant papers. Then the general flow of RUL prediction and an in-depth introduction to the four most used signal pre-processing techniques in RUL prediction are presented. The research core of common ML algorithms is given first time in a uniform format in chronological order. The algorithms are also compared from aspects of accuracy and characteristics comprehensively, and the novel and general improvement directions or opportunities including improvement in early prediction, local regeneration modeling, physical information fusion, generalized transfer learning, and hardware implementation are further outlooked. Finally, the methods of battery lifetime extension are summarized, and the feasibility of using RUL as an indicator for extending battery lifetime is outlooked. Battery lifetime can be extended by optimizing the charging profile serval times according to the accurate RUL prediction results online in the future. This paper aims to give inspiration to the future improvement of ML algorithms in battery RUL prediction and lifetime extension strategy.
    Design strategy and comprehensive performance assessment towards Zn anode for alkaline rechargeable batteries
    Di Yang, Jinsheng Li, Changpeng Liu, Wei Xing, Jianbing Zhu
    2023, 82(7): 122-138.  DOI: 10.1016/j.jechem.2023.03.049
    Abstract ( 9 )   PDF (15629KB) ( 7 )  
    Alkaline Zn-based primary batteries have been commercialized in the past decades. However, their success has not been extended to secondary batteries due to the poor cycle reversibility of Zn anodes. Although some research has been conducted on alkaline Zn anodes, their performance is still far from commercial requirements. A variety of degradation mechanisms, including passivation, dendrites, morphological changes, and hydrogen precipitation, are claimed responsible for the failure of alkaline Zn metal anodes. What's worse, these constraints always interact with each other, which leads to a single strategy being unable to suppress all the issues. Therefore, a comprehensive evaluation of the positive and negative effects of various strategies on performance is important to promote the commercialization of alkaline Zn batteries. Herein, the recent progress and performance of improvement strategies for Zn anode in alkaline conditions are reviewed systematically. First, the principles and challenges of alkaline Zn anodes are briefly analyzed. Then, various design strategies for alkaline Zn anodes from the perspectives of ion and electron regulation are highlighted. Last, through a comprehensive summary of various performance parameters, the advantages and disadvantages of different strategies are compared and evaluated. On the basis of this assessment, we aim to provide more insights into the anode design of high-performance alkaline rechargeable Zn batteries.
    Predicting power conversion efficiency of binary organic solar cells based on Y6 acceptor by machine learning
    Qiming Zhao, Yuqing Shan, Chongchen Xiang, Jinglun Wang, Yingping Zou, Guangjun Zhang, Wanqiang Liu
    2023, 82(7): 139-147.  DOI: 10.1016/j.jechem.2023.03.030
    Abstract ( 24 )   PDF (4618KB) ( 11 )  
    Organic solar cells (OSCs) are a promising photovoltaic technology for practical applications. However, the design and synthesis of donor materials molecules based on traditional experimental trial-and-error methods are often complex and expensive in terms of money and time. Machine learning (ML) can effectively learn from data sets and build reliable models to predict the performance of materials with reasonable accuracy. Y6 has become the landmark high-performance OSC acceptor material. We collected the power conversion efficiency (PCE) of small molecular donors and polymer donors based on the Y6 acceptor and calculated their molecule structure descriptors. Then we used six types of algorithms to develop models and compare the predictive performance with the coefficient of determination (R2) and Pearson correlation coefficient (r) as the metrics. Among them, decision tree-based algorithms showed excellent predictive capability, especially the Gradient Boosting Regression Tree (GBRT) models based on small molecular donors and polymer donors exhibited that the values of R2 are 0.84 and 0.69 for the testing set, respectively. Our work provides a strategy to predict PCEs rapidly, and discovers the influence of the descriptors, thereby being expected to screen high-performance donor material molecules.
    Upcycling end of lithium cobalt oxide batteries to electrocatalyst for oxygen reduction reaction in direct methanol fuel cell via sustainable approach
    Keyru Serbara Bejigo, Kousik Bhunia, Jungho Kim, Chaehyeon Lee, Seoin Back, Sang-Jae Kim
    2023, 82(7): 148-157.  DOI: 10.1016/j.jechem.2023.03.042
    Abstract ( 7 )   PDF (9603KB) ( 5 )  
    Recycling spent lithium-ion batteries (SLIBs) has become essential to preserve the environment and reclaim vital resources for sustainable development. The typical SLIBs recycling concentrated on separating valuable components had limitations, including high energy consumption and complicated separation processes. This work suggests a safe hydrometallurgical process to recover usable metallic cobalt from depleted LiCoO2 batteries by utilizing citric acid as leachant and hydrogen peroxide as an oxidizing agent, with ethanol as a selective precipitating agent. The anode graphite was also recovered and converted to graphene oxide (GO). The above components were directly resynthesized to cobalt-integrated nitrogen-doped graphene (Co@NG). The Co@NG showed a decent activity towards oxygen reduction reaction (ORR) with a half-wave potential of 0.880 V vs. RHE, almost similar to Pt/C (0.888 V vs. RHE) and with an onset potential of 0.92 V vs. RHE. The metal-nitrogen-carbon (Co-N-C) having the highest nitrogen content has decreased the barrier for ORR since the reaction was enhanced for Co@NG-800, as confirmed by density functional theory (DFT) simulations. The Co@NG cathode catalyst coupled with commercial Pt-Ru/C as anode catalyst exhibits excellent performance for direct methanol fuel cell (DMFC) with a peak power density of 34.7 mW cm-2 at a discharge current density of 120 mA cm-2 and decent stability, indicating the promising utilization of spent battery materials in DMFC applications. Besides, lithium was recovered from supernatant as lithium carbonate by coprecipitation process. This work avoids sophisticated elemental separation by utilizing SLIBs for other renewable energy applications, lowering the environmental concerns associated with recycling.
    Reversible cationic-anionic redox in disordered rocksalt cathodes enabled by fluorination-induced integrated structure design
    Feng Wu, Jinyang Dong, Jiayu Zhao, Qi Shi, Yun Lu, Ning Li, Duanyun Cao, Wenbo Li, Jianan Hao, Yu Zheng, Lai Chen, Yuefeng Su
    2023, 82(7): 158-169.  DOI: 10.1016/j.jechem.2023.03.048
    Abstract ( 20 )   PDF (21463KB) ( 15 )  
    Cation-disordered rocksalt oxides (DRX) have been identified as promising cathode materials for high energy density applications owing to their variable elemental composition and cationic-anionic redox activity. However, their practical implementation has been impeded by unwanted phenomena such as irrepressible transition metal migration/dissolution and O2/CO2 evolution, which arise due to parasitic reactions and densification-degradation mechanisms during extended cycling. To address these issues, a micron-sized DRX cathode Li1.2Ni1/3Ti1/3W2/15O1.85F0.15 (SLNTWOF) with F substitution and ultrathin LiF coating layer is developed by alcohols assisted sol-gel method. Within this fluorination-induced integrated structure design (FISD) strategy, in-situ F substitution modifies the activity/reversibility of the cationic-anionic redox reaction, while the ultrathin LiF coating and single-crystal structure synergistically mitigate the cathode/electrolyte parasitic reaction and densification-degradation mechanism. Attributed to the multiple modifications and size effect in the FISD strategy, the SLNTWOF sample exhibits reversible cationic-anionic redox chemistry with a meliorated reversible capacity of 290.3 mA h g-1 at 0.05C (1C = 200 mA g-1), improved cycling stability of 78.5% capacity retention after 50 cycles at 0.5 C, and modified rate capability of 102.8 mA h g-1 at 2 C. This work reveals that the synergistic effects between bulk structure modification, surface regulation, and engineering particle size can effectively modulate the distribution and evolution of cationic-anionic redox activities in DRX cathodes.
    Latest progresses and the application of various electrolytes in high-performance solid-state lithium-sulfur batteries
    Yanan Li, Nanping Deng, Hao Wang, Qiang Zeng, Shengbin Luo, Yongbing Jin, Quanxiang Li, Weimin Kang, Bowen Cheng
    2023, 82(7): 170-197.  DOI: 10.1016/j.jechem.2023.03.045
    Abstract ( 11 )   PDF (22053KB) ( 12 )  
    With the emergence of some solid electrolytes (SSEs) with high ionic conductivity being comparable to liquid electrolytes, solid-state lithium-sulfur batteries (SSLSBs) have been widely regarded as one of the most promising candidates for the next generation of power generation energy storage batteries, and have been extensively researched. Though many fundamental and technological issues still need to be resolved to develop commercially viable technologies, SSLSBs using SSEs are expected to address the present limitations and achieve high energy and power density while improving safety, which is very attractive to large-scale energy storage systems. SSLSBs have been developed for many years. However, there are few systematic discussions related to the working mechanism of action of various electrolytes in SSLSBs and the defects and the corresponding solutions of various electrolytes. To fill this gap, it is very meaningful to review the recent progress of SSEs in SSLSBs. In this review, we comprehensively investigate and summarize the application of SSEs in LSBs to determine the differences which still exist between current progresses and real-world requirements, and comprehensively describe the mechanism of action of SSLSBs, including lithium-ion transport, interfacial contact, and catalytic conversion mechanisms. More importantly, the selection of solid electrolyte materials and the novel design of structures are reviewed and the properties of various SSEs are elucidated. Finally, the prospects and possible future research directions of SSLSBs including designing high electronic/ionic conductivity for cathodes, optimizing electrolytes and developing novel electrolytes with excellent properties, improving electrode/electrolyte interface stability and enhancing interfacial dynamics between electrolyte and anode, using more advanced test equipment and characterization techniques to analyze conduction mechanism of Li+ in SSEs are presented. It is hoped that this review can arouse people's attention and enlighten the development of functional materials and novel structures of SSEs in the next step.
    Efficient proton conduction in porous and crystalline covalent-organic frameworks (COFs)
    Liyu Zhu, Huatai Zhu, Luying Wang, Jiandu Lei, Jing Liu
    2023, 82(7): 198-218.  DOI: 10.1016/j.jechem.2023.04.002
    Abstract ( 16 )   PDF (26184KB) ( 7 )  
    To attain the objectives of carbon peaking and carbon neutrality, the development of stable and high-performance ion-conducting materials holds enormous relevance in various energy storage and conversion devices. Particularly, crystalline porous materials possessing built-in ordered nanochannels exhibit remarkable superiority in comprehending the ion transfer mechanisms with precision. In this regard, covalent organic frameworks (COFs) are highly regarded as a promising alternative due to their pre-eminent structural tunability, accessible well-defined pores, and excellent thermal/chemical stability under hydrous/anhydrous conditions. By the availability of organic units and the diversity of topologies and connections, advances in COFs have been increasing rapidly over the last decade and they have emerged as a new field of proton-conducting materials. Therefore, a comprehensive summary and discussion are urgently needed to provide an “at a glance” understanding of the prospects and challenges in the development of proton-conducting COFs. In this review, we target a comprehensive review of COFs in the field of proton conductivity from the aspects of design strategies, the proton conducting mechanism/features, the relationships of structure-function, and the application of research. The relevant content of theoretical simulation, advanced structural characterizations, prospects, and challenges are also presented elaborately and critically. More importantly, we sincerely hope that this progress report will form a consistent view of this field and provide inspiration for future research.
    Molecular exchange and passivation at interface afford high-performing perovskite solar cells with efficiency over 24%
    Jianjun Sun, Wangchao Chen, Yingke Ren, Yunjuan Niu, Zhiqian Yang, Li'e Mo, Yang Huang, Zhaoqian Li, Hong Zhang, Linhua Hu
    2023, 82(7): 219-227.  DOI: 10.1016/j.jechem.2023.03.003
    Abstract ( 12 )   PDF (8129KB) ( 9 )  
    The interface is crucial for perovskite solar cells (PSCs). However, voids at interfaces induced by the trapped hygroscopic dimethyl sulfoxide (DMSO) can reduce charge extraction and accelerate the film degradation, seriously damaging the efficiency and stability. In this work, 4,4′-dinonyl-2,2′-dipyridine (DN-DP), a Lewis base with long alkyl chains is introduced to solve this problem. Theoretical calculated and experimental results confirm that the dipyridyl group on DN-DP can more strongly coordinate with Pb2+ than that of the S=O group on DMSO. The strong coordination effect plays a crucial role in removing the DMSO-based adduct and reducing the formation of voids. Due to the electron-donating properties of pyridine, the existence of DN-DP in the perovskite film can passivate the defects and optimize the energy level alignment of the perovskite configuration. The open-circuit voltage (VOC) of the DN-DP-based PSC is improved from 1.107 V (control device) to 1.153 V, giving rise to a power conversion efficiency (PCE) of 24.02%. Furthermore, benefiting from the moisture resistance stemming from the hydrophobic nonyl group, the PCE retains 90.4% of the initial performance after 1000 h of storage in the ambient condition.
    One-step electrochemical in-situ Li doping and LiF coating enable ultra-stable cathode for sodium ion batteries
    Jiameng Feng, Chaoliang Zheng, De Fang, Jianling Li
    2023, 82(7): 228-238.  DOI: 10.1016/j.jechem.2023.03.014
    Abstract ( 6 )   PDF (11025KB) ( 4 )  
    Despite of the higher energy density and inexpensive characteristics, commercialization of layered oxide cathodes for sodium ion batteries (SIBs) is limited due to the lack of structural stability at the high voltage. Herein, the one-step electrochemical in-situ Li doping and LiF coating are successfully achieved to obtain an advanced Na0.79Lix[Li0.13Ni0.20Mn0.67]O2@LiF (NaLi-LNM@LiF) cathode with superlattice structure. The results demonstrate that the Li+ doped into the alkali metal layer by electrochemical cycling act as “pillars” in the form of Li-Li dimers to stabilize the layered structure. The supplementation of Li to the superlattice structure inhibits the dissolution of transition metal ions and lattice mismatch. Furthermore, the in-situ LiF coating restrains side reactions, reduces surface cracks, and greatly improves the cycling stability. The electrochemical in-situ modification strategy significantly enhances the electrochemical performance of the half-cell. The NaLi-LNM@LiF exhibits high reversible specific capacity (170.6 mA h g-1 at 0.05 C), outstanding capacity retention (92.65% after 200 cycles at 0.5 C) and excellent rate performance (80 mA h g-1 at 7 C) in a wide voltage range of 1.5-4.5 V. This novel method of in-situ modification by electrochemical process will provide a guidance for the rational design of cathode materials for SIBs.
    Molecular insight into the GaP(110)-water interface using machine learning accelerated molecular dynamics
    Xue-Ting Fan, Xiao-Jian Wen, Yong-Bin Zhuang, Jun Cheng
    2023, 82(7): 239-247.  DOI: 10.1016/j.jechem.2023.03.013
    Abstract ( 6 )   PDF (8112KB) ( 5 )  
    GaP has been shown to be a promising photoelectrocatalyst for selective CO2 reduction to methanol. Due to the relevance of the interface structure to important processes such as electron/proton transfer, a detailed understanding of the GaP(110)-water interfacial structure is of great importance. Ab initio molecular dynamics (AIMD) can be used for obtaining the microscopic information of the interfacial structure. However, the GaP(110)-water interface cannot converge to an equilibrated structure at the time scale of the AIMD simulation. In this work, we perform the machine learning accelerated molecular dynamics (MLMD) to overcome the difficulty of insufficient sampling by AIMD. With the help of MLMD, we unravel the microscopic information of the structure of the GaP(110)-water interface, and obtain a deeper understanding of the mechanisms of proton transfer at the GaP(110)-water interface, which will pave the way for gaining valuable insights into photoelectrocatalytic mechanisms and improving the performance of photoelectrochemical cells.
    Hollow sphere of heterojunction (NiCu)S/NC as advanced anode for sodium-ion battery
    Hongyi Chen, Pengfei Lv, Pengfu Tian, Shiyue Cao, Shengjun Yuan, Qiming Liu
    2023, 82(7): 248-258.  DOI: 10.1016/j.jechem.2023.03.018
    Abstract ( 11 )   PDF (15563KB) ( 13 )  
    Metal sulfide is considered as a potential anode for sodium-ion batteries (SIBs), due to the high theoretical capacity, strong thermodynamic stability and low-cost. However, their cycle capacity and rate performance are limited by the excessive expansion rate and low intrinsic conductivity. Herein, heterogeneous hollow sphere NiS-Cu9S5/NC (labeled as (NiCu)S/NC) based on Oswald ripening mechanism was prepared through a simple and feasible methodology. From a structural perspective, the hollow structure provides an expansion buffer and raises the electrochemical active area. In terms of electron/ion during the cycles, Na+ storage mechanism is optimized by NiS/Cu9S5 heterogeneous interface, which increases the storage sites and shortens the migration path of Na+. The formation of built-in electric field strengthens the electron/ion mobility. Based on the first principle calculations, it is further proved the formation of heterogeneous interfaces and the direction of electron flow. As the anode for SIBs, the synthesized (NiCu)S/NC delivers high reverse capacity (559.2 mA h g-1 at 0.5 A g-1), outstanding rate performance (185.3 mA h g-1 at 15 A g-1), long-durable stability (342.6 mA h g-1 at 4 A g-1 after 1500 cycles, 150.0 mA h g-1 at 10 A g-1 after 20,000 cycles with 0.0025% average attenuation rate). The matching cathode electrode Na3V2(PO4)3/C is assembled with (NiCu)S/NC for the full-battery that achieves high energy density (253.7 W h kg-1) and reverse capacity (288.7 mA h g-1). The present work provides a distinctive strategy for constructing electrodes with excellent capacity and stability for SIBs.
    Oxygen-defects evolution to stimulate continuous capacity increase in Co-free Li-rich layered oxides
    Yibin Zhang, Xiaohui Wen, Zhepu Shi, Bao Qiu, Guoxin Chen, Zhaoping Liu
    2023, 82(7): 259-267.  DOI: 10.1016/j.jechem.2023.03.005
    Abstract ( 11 )   PDF (12034KB) ( 2 )  
    Though oxygen defects are associated with deteriorated structures and aggravated cycling performance in traditional layered cathodes, the role of oxygen defects is still ambiguous in Li-rich layered oxides due to the involvement of oxygen redox. Herein, a Co-free Li-rich layered oxide Li1.286Ni0.071Mn0.643O2 has been prepared by a co-precipitation method to systematically investigate the undefined effects of the oxygen defects. A significant O2 release and the propagation of oxygen vacancies were detected by operando differential electrochemical mass spectroscopy (DEMS) and electron energy loss spectroscopy (EELS), respectively. Scanning transmission electron microscopy-high angle annular dark field (STEM-HAADF) reveals the oxygen vacancies fusing to nanovoids and monitors a stepwise electrochemical activation process of the large Li2MnO3 domain upon cycling. Combined with the quantitative analysis conducted by the energy dispersive spectrometer (EDS), existed nano-scale oxygen defects actually expose more surface to the electrolyte for facilitating the electrochemical activation and subsequently increasing available capacity. Overall, this work persuasively elucidates the function of oxygen defects on oxygen redox in Co-free Li-rich layered oxides.
    Synergy mechanism of defect engineering in MoS2/FeS2/C heterostructure for high-performance sodium-ion battery
    Linlin Ma, Xiaomei Zhou, Jun Sun, Pan Zhang, Baoxiu Hou, Shuaihua Zhang, Ningzhao Shang, Jianjun Song, Hongjun Ye, Hui Shao, Yongfu Tang, Xiaoxian Zhao
    2023, 82(7): 268-276.  DOI: 10.1016/j.jechem.2023.03.011
    Abstract ( 11 )   PDF (9407KB) ( 10 )  
    MoS2 is a promising anode material in sodium-ion battery technologies for possessing high theoretical capacity. However, the sluggish Na+ diffusion kinetics and low electronic conductivity hinder the promises. Herein, a unique MoS2/FeS2/C heterojunction with abundant defects and hollow structure (MFCHHS) was constructed. The synergy of defect engineering in MoS2, FeS2, and the carbon layer of MFCHHS with a larger specific surface area provides multiple storage sites of Na+ corresponding to the surface-controlled process. The MoS2/FeS2/C heterostructure and rich defects in MoS2 and carbon layer lower the Na+ diffusion energy barrier. Additionally, the construction of MoS2/FeS2 heterojunction promotes electron transfer at the interface, accompanying with excellent conductivity of the carbon layer to facilitate reversible electrochemical reactions. The abundant defects and mismatches at the interface of MoS2/FeS2 and MoS2/C heterojunctions could relieve lattice stress and volume change sequentially. As a result, the MFCHHS anode exhibits the high capacity of 613.1 mA h g-1 at 0.5 A g-1 and 306.1 mA h g-1 at 20 A g-1. The capacity retention of 85.0% after 1400 cycles at 5.0 A g-1 is achieved. The density functional theory (DFT) calculation and in situ transmission electron microscope (TEM), Raman, ex-situ X-ray photon spectroscopy (XPS) studies confirm the low volume change during intercalation/deintercalation process and the efficient Na+ storage in the layered structure of MoS2 and carbon layer, as well as the defects and heterostructures in MFCHHS. We believe this work could provide an inspiration for constructing heterojunction with abundant defects to foster fast electron and Na+ diffusion kinetics, resulting in excellent rate capability and cycling stability.
    Electrodeposited copper oxides with a suppressed interfacial amorphous phase using mixed-crystalline ITO and their enhanced photoelectrochemical performances
    Ji Hoon Choi, Hae-Jun Seok, Dongchul Sung, Dong Su Kim, Hak Hyeon Lee, Suklyun Hong, Han-Ki Kim, Hyung Koun Cho
    2023, 82(7): 277-286.  DOI: 10.1016/j.jechem.2023.03.040
    Abstract ( 4 )   PDF (8885KB) ( 6 )  
    The effectiveness of photoelectrochemical (PEC) water splitting is significantly restricted by insufficient light harvesting, rapid charge recombination, and slow water reduction kinetics. Since the presence of amorphous phases in the interfaces hinders the overcome of these inherent limitations, a photoelectrode must be built strategically. Herein, we artificially controlled the crystallographic orientation of indium tin oxide (ITO) to determine the orientation with the smallest lattice mismatch at the Cu2O interface, thus significantly reducing the amorphous phase in the early stage of electrodeposition nucleation. The [222]/[400] mixed orientation ITO primarily exposed the {400} surface planes and accelerated charge transfer by forming an optimal interface with preferentially grown (111) oriented Cu2O and minimized amorphous region. In addition, the ITO surface energy was calculated using density functional theory to theoretically verify which plane is more active for growing the photoactivation layer. The rationally designed ITO/Cu2O/Al-dope ZnO/TiO2/Rh-P device, with each layer serving a specific purpose, achieved a photocurrent density of 8.23 mA cm-2 at 0 VRHE under AM 1.5 G illumination, providing a standard method for effective solar-to-hydrogen conversion photocathodes.
    Non-solvating fluorosulfonyl carboxylate enables temperature-tolerant lithium metal batteries
    Xianshu Wang, Junru Wu, Yun Zhao, Bin Li, Naser Tavajohi, Qi Liu, Jianguo Duan, Ding Wang, Peng Dong, Yingjie Zhang, Baohua Li
    2023, 82(7): 287-295.  DOI: 10.1016/j.jechem.2023.02.051
    Abstract ( 8 )   PDF (10699KB) ( 2 )  
    Advanced electrolyte engineering is an important strategy for developing high-efficacy lithium (Li) metal batteries (LMBs). Unfortunately, the current electrolytes limit the scope for creating batteries that perform well over temperature ranges. Here, we present a new electrolyte design that uses fluorosulfonyl carboxylate as a non-solvating solvent to form difluoroxalate borate (DFOB-) anion-rich solvation sheath, to realize high-performance working of temperature-tolerant LMBs. With this optimized electrolyte, favorable SEI and CEI chemistries on Li metal anode and nickel-rich cathode are achieved, respectively, leading to fast Li+ transfer kinetics, dendrite-free Li deposition and suppressed electrolyte deterioration. Therefore, Li||LiNi0.80Co0.15Al0.05O2 batteries with a thin Li foil (50 μm) show a long-term cycling lifespan over 400 cycles at 1C and a superior capacity retention of 90% after 200 cycles at 0.5C under 25 ℃. Moreover, this electrolyte extends the operating temperature from -10 to 30 ℃ and significantly improve the capacity retention and Coulombic efficiency of batteries are improved at high temperature (60 ℃). Fluorosulfonyl carboxylates thus have considerable potential for use in high-performance and all-weather LMBs, which broadens the new exploring of electrolyte design.
    Halogen chlorine triggered oxygen vacancy-rich Ni(OH)2 with enhanced reaction kinetics for pseudocapacitive energy storage
    Jiangyu Hao, Lijin Yan, Liang Luo, Qiaohui Liu, Youcun Bai, Yuying Han, Yang Zhou, Xuefeng Zou, Bin Xiang
    2023, 82(7): 296-306.  DOI: 10.1016/j.jechem.2023.03.025
    Abstract ( 8 )   PDF (13582KB) ( 3 )  
    Two-dimensional (2D) Ni(OH)2 nanosheets can theoretically expose their active sites of 100%. Whereas, their intrinsic easy accumulation and low conductivity lead to weak and unsustainable reaction kinetics. Herein, we propose a novel halogen chlorine-triggered electrochemical etching strategy to controllably manage the reaction kinetics of 2D Ni(OH)2 nanosheets (EE/Cl-Ni(OH)2). It is found that halogen chlorine doping can adjust the interlamellar spacing flexibly and promote the lattice oxygen activation to achieve controlled construction of superficial oxygen defects at the adjustable voltage. The optimal EE/Cl-Ni(OH)2 electrode exhibits a high rate capability and excellent specific capacity of 206.9 mA h g-1 at 1 A g-1 in a three-electrode system, which is more than twice as high as the pristine Ni(OH)2. Furthermore, EE/Cl-Ni(OH)2 cathode and FeOOH@rGO anode are employed for developing an aqueous Ni-Fe battery with an excellent energy density of 83 W h kg-1, a high power density of 17051 W kg-1, and robust durability over 20,000 cycles. This strategy exploits a fresh channel for the ingenious fabrication of high-efficiency and stable nickel-based deficiency materials for energy storage.
    Design of high-performance ion-doped CoP systems for hydrogen evolution: From multi-level screening calculations to experiment
    Xiaofei Cao, Siqian Xing, Duo Ma, Yuan Tan, Yucheng Zhu, Jun Hu, Yao Wang, Xi Chen, Zhong Chen
    2023, 82(7): 307-316.  DOI: 10.1016/j.jechem.2023.03.043
    Abstract ( 6 )   PDF (8114KB) ( 4 )  
    Rational design of high-performance electrocatalysts for hydrogen evolution reaction (HER) is vital for future renewable energy systems. The incorporation of foreign metal ions into catalysts can be an effective approach to optimize its performance. However, there is a lack of systematic theoretical studies to reveal the quantitative relationships at the electronic level. Here, we develop a multi-level screening methodology to search for highly stable and active dopants for CoP catalysts. The density functional theory (DFT) calculations and symbolic regression (SR) were performed to investigate the relationship between the adsorption free energy (ΔGH*) and 10 electronic parameters. The mathematic formulas derived from SR indicate that the difference of work function (ΔΦ) between doped metal and the acceptor plays the most important role in regulating ΔGH*, followed by the d-band center (d-BC) of doped system. The descriptor of HER can be expressed as $ \Delta G_{\mathrm{H}^{*}}=1.59 \times \sqrt{|0.188 \Delta \Phi+d B C+0.120|}-0.166$ with a high determination coefficient (R2 = 0.807). Consistent with the theoretical prediction, experimental results show that the Al-CoP delivers superior electrocatalytic HER activity with a low overpotential of 75 mV to drive a current density of 10 mA cm-2, while the overpotentials for undoped CoP, Mo-CoP, and V-CoP are 206, 134, and 83 mV, respectively. The current work proves that the ΔΦ is the most significant regulatory parameter of ΔGH* for ion-doped electrocatalysts. This finding can drive the discovery of high-performance ion-doped electrocatalysts, which is crucial for electrocatalytic water splitting.
    Microscopic study on the key process and influence of efficient synthesis of natural gas hydrate by in situ Raman analysis of water microstructure in different systems with temperature drop
    Wei Zhang, Chun-Gang Xu, Xiao-Sen Li, Zhuo-Yi Huang, Zhao-Yang Chen
    2023, 82(7): 317-333.  DOI: 10.1016/j.jechem.2023.03.029
    Abstract ( 7 )   PDF (1248KB) ( 4 )  
    Gas hydrate technology has considerable potential in many fields. However, due to the lack of understanding of the micro mechanism of hydrate formation, it has not been commercially applied so far. Gas hydrate formation is essentially a gas-liquid-solid phase transition of water and gas molecules at a certain temperature and pressure. The key to the hydrate formation is the transformation of water molecule from disordered arrangement to ordered arrangement. In this process, weakly hydrogen bonded water will be correspondingly converted to strongly hydrogen bonded water. Through in situ Raman analysis and experiments, the position change of the corresponding peaks of the strongly hydrogen bonded water and the weakly hydrogen bonded water was compared in this work, and the key microscopic process and influence of gas hydrate formation in different systems were comprehensively studied and summarized. It is found that, with the decrease of temperature, the O-H of the weakly hydrogen bonded water remains unchanged when the temperature drops to a certain value, which is the key to the transformation of water into cage hydrate rather than ice. The conversion from the weakly hydrogen bonded water to the strongly hydrogen bonded water is closely related to the gas-liquid interface force, the hydrophilicity/hydrophobicity of the promoter, the ionization degree of liquid, and the electrostatic field of the system. Among the four most common promoters, tetrahydrofuran (THF) has the highest efficiency in promoting methane (CH4) hydrate formation. Therefore, this study provides a scientific direction and basis for the development of high efficient hydrate formation promoters, which can effectively weaken the hydrogen bond of weakly hydrogen bonded water and promote the conversion of weakly hydrogen bonded water to strongly hydrogen bonded water.
    A novel perylene diimide-based ionene polymer and its mixed cathode interlayer strategy for efficient and stable inverted perovskite solar cells
    Daizhe Wang, Cong Kang, Tengling Ye, Dongqing He, Shan Jin, Xiaoru Zhang, Xiaochen Sun, Yong Zhang
    2023, 82(7): 334-342.  DOI: 10.1016/j.jechem.2023.03.032
    Abstract ( 18 )   PDF (7841KB) ( 16 )  
    Inverted (p-i-n) perovskite solar cells (PerSCs) have attracted much attention owing to their low temperature processability, less hysteresis effect and easy integration as a subunit for the tandem device. The unsatisfactory interface contacts and energy level barrier between adjacent interlayers on the cathode side are one of the key challenges for the development of p-i-n PerSCs. Herein, perylene diimide-based (PDI) ionene polymer was synthesized and developed as a cathode interlayer (CIL) to enhance interface contact, reduce the energy level barrier and prevent the migration of I- ions. The compact PNPDI CIL with high conductivity and appropriate lowest unoccupied molecular orbital (LUMO) level, resulted in a high efficiency device (20.03%), which is higher than the control device with bathophenanthroline (Bphen) (19.48%). Bphen-based CIL shows better adjusting ability of the work function of cathode metal but exhibits poor film-forming property. So, the synergistic effect of 1 + 1 > 2 can be obtained by combining Bphen and PNPDI into one CIL. As expected, the device performance was further improved by using the mixed CIL of Bphen and PNPDI, and 21.46% power conversion efficiency (PCE) was achieved. What's more, the compact and hydrophobic mixed CIL dramatically enhanced the resistance to I- ions and moisture, which led to much enhanced device stability.
    Rh-Cu alloy nano-dendrites with enhanced electrocatalytic ethanol oxidation activity
    Di Liu, Zhejiaji Zhu, Jiani Li, Li-Wei Chen, Hui-Zi Huang, Xiao-Ting Jing, An-Xiang Yin
    2023, 82(7): 343-349.  DOI: 10.1016/j.jechem.2023.03.038
    Abstract ( 3 )   PDF (6139KB) ( 4 )  
    The application of direct ethanol fuel cell (DEFC) has been bottlenecked by the sluggish ethanol oxidation reaction (EOR). Efficient electrocatalysts for the C-C bond cleavage are essential to promote EOR with high efficiency and C1 selectivity. Here, we prepared Rh-Cu alloy nano-dendrites (RhCu NDs) with abundant surface steps through controlled co-reduction, which exhibited significantly enhanced activity and C1 selectivity (0.47 mA cm-2(ECSA), 472.4 mA mgRh-1, and 38.9%) than Rh NDs (0.32 mA cm-2(ECSA), 322.1 mA mgRh-1, and 21.4%) and commercially available Rh/C (0.18 mA cm-2(ECSA), 265.4 mA mgRh-1, and 14.9%). Theoretical calculations and CO-stripping experiments revealed that alloying with Cu could modulate the surface electronic structures of Rh to resist CO-poisoning while strengthening ethanol adsorption. In situ Fourier transform infrared spectroscopy (FTIR) indicated that the surface steps on RhCu NDs further promoted the C-C bond cleavage to increase the C1 selectivity. Therefore, optimizing the surface geometric and electronic structures of nanocrystals by rational composition and morphology control can provide a promising strategy for developing practical DEFC devices.
    Revealing alkali metal ions transport mechanism in the atomic channels of Au@α-MnO2
    Jingzhao Chen, Yong Su, Hongjun Ye, Yushu Tang, Jitong Yan, Zhiying Gao, Dingding Zhu, Jingming Yao, Xuedong Zhang, Tingting Yang, Baiyu Guo, Hui Li, Qiushi Dai, Yali Liang, Jun Maa, Bo Wang, Haiming Sun, Qiunan Liu, Jing Wang, Congcong Du, Liqiang Zhang, Yongfu Tang, Jianyu Huang
    2023, 82(7): 350-358.  DOI: 10.1016/j.jechem.2023.03.044
    Abstract ( 6 )   PDF (9126KB) ( 6 )  
    Understanding alkali metal ions' (e.g., Li+/Na+/K+) transport mechanism is challenging but critical to improving the performance of alkali metal batteries. Herein using α-MnO2 nanowires as cathodes, the transport kinetics of Li+/Na+/K+ in the 2 × 2 channels of α-MnO2 with a growth direction of [001] is revealed. We show that ion radius plays a decisive role in determining the ion transport and electrochemistry. Regardless of the ion radii, Li+/Na+/K+ can all go through the 2 × 2 channels of α-MnO2, generating large stress and causing channel merging or opening. However, smaller ions such as Li+ and Na+ cannot only transport along the [001] direction but also migrate along the < 110 > direction to the nanowire surface; for large ion such as K+, diffusion along the < 110 > direction is prohibited. The different ion transport behavior has grand consequences in the electrochemistry of metal oxygen batteries (MOBs). For Li-O2 battery, Li+ transports uniformly to the nanowire surface, forming a uniform layer of oxide; Na+ also transports to the nanowire surface but may be clogged locally due to its larger radius, therefore sporadic pearl-like oxides form on the nanowire surface; K+ cannot transport to the nanowire surface due to its large radius, instead, it breaks the nanowire locally, causing local deposition of potassium oxides. The study provides atomic scale understanding of the alkali metal ion transport mechanism which may be harnessed to improve the performance of MOBs.
    The effect of pH on stability and thermal performance of graphene oxide and copper oxide hybrid nanofluids for heat transfer applications: Application of novel machine learning technique
    Praveen Kumar Kanti, Prabhakar Sharma, K.V. Sharma, M.P. Maiya
    2023, 82(7): 359-374.  DOI: 10.1016/j.jechem.2023.04.001
    Abstract ( 14 )   PDF (21414KB) ( 10 )  
    This paper investigates the effects of pH on stability and thermal properties of copper oxide (CuO), graphene oxide (GO), and their hybrid nanofluid (HNF) at different mixing ratios. Initially, sol-gel and Hummer's method was employed for the synthesis of CuO and GO nanoparticles (NPs), and they are characterized with various techniques. The effects of two different surfactants were analyzed on nanofluid's (NF's) stability at different pH values. The properties like thermal conductivity (TC) and viscosity (VST) of NFs were measured at different volume concentration (0.1 vol% to 1.0 vol%) and temperature range of 30-60 °C, respectively. The TC and VST of GO/CuO (50:50) HNF are higher than that of GO/CuO (20:80). The figure of merit (FOM) is determined for the studied HNFs. The correlations were presented to calculate the TC as well as VST of HNFs. Two modern novel machine learning-based ensemble approaches were employed for predictive model development for TC and VST of considered HNFs. The comparison of prognostic models with Taylor's diagram revealed that Bayesian optimized support vector machine (BoA-SVM) was superior to Bayesian optimized boosted regression trees (BoA-BRT) for both TC and VST models.
    Building up a general selection strategy and catalytic performance prediction expressions of heteronuclear double-atom catalysts for N2 reduction
    Yibo Wu, Cheng He, Wenxue Zhang
    2023, 82(7): 375-386.  DOI: 10.1016/j.jechem.2023.03.024
    Abstract ( 5 )   PDF (11079KB) ( 5 )  
    The severe environmental problems and the demand for energy urgently require electrocatalysis to replace Haber-Bosch for the nitrogen reduction reaction (NRR). The descriptors and important properties of single-atom and homonuclear double-atom catalysts have been preliminarily explored, but the relationship between the inherent properties and catalytic activity of heteronuclear double-atom catalysts with better performance remains unclear. Therefore, it is very significant to explore the prediction expressions of catalytic activity of heteronuclear double-atom catalysts based on their inherent properties and find the rule for selecting catalytic centers. Herein, by summarizing the free energy for the key steps of NRR on 55 catalysts calculated through the first-principle, the expressions of predicting the free energy and the corresponding descriptors are deduced by the machine learning, and the strategy for selecting the appropriate catalytic center is proposed. The selection strategy for the central atom of heteronuclear double-atom catalysts is that the atomic number of central B atom should be between group VB and VIIIB, and the electron difference between central A atom and B atom should be large enough, and the selectivity of NRR or hydrogen evolution reaction (HER) could be calculated through the prediction formula. Moreover, five catalysts are screened to have low limiting potential and excellent selectivity, and are further analyzed by electron transfer. This work explores the relationship between the inherent properties of heteronuclear double-atom catalysts and the catalytic activity, and puts forward the rules for selecting the heteronuclear double-atom catalytic center, which has guiding significance for the experiment.
    Self-adaptive bulk/surface engineering of BixOyBrz towards enhanced photocatalysis: Current status and future challenges
    Zhiwei Wu, Bidyut Kumar Kundu, Wanqiong Kang, Lei Mao, Sen Zhang, Lan Yuan, Fen Guo, Chuang Han
    2023, 82(7): 387-413.  DOI: 10.1016/j.jechem.2023.02.043
    Abstract ( 13 )   PDF (22374KB) ( 4 )  
    The bulk/surface states of semiconductor photocatalysts are imperative parameters to maneuver their performance by significantly affecting the key processes of photocatalysis including light absorption, separation of charge carrier, and surface site reaction. Recent years have witnessed the encouraging progress of self-adaptive bulk/surface engineered BixOyBrz for photocatalytic applications spanning various fields. However, despite the maturity of current research, the interaction between the bulk/surface state and the performance of BixOyBrz has not yet been fully understood and highlighted. In this regard, a timely tutorial overview is quite urgent to summarize the most recent key progress and outline developing obstacles in this exciting area. Herein, the structural characteristics and fundamental principles of BixOyBrz for driving photocatalytic reaction as well as related key issues are firstly reviewed. Then, we for the first time summarized different self-adaptive engineering processes over BixOyBrz followed by a classification of the generation approaches towards diverse BixOyBrz materials. The features of different strategies, the up-to-date characterization techniques to detect bulk/surface states, and the effect of bulk/surface states on improving the photoactivity of BixOyBrz in expanded applications are further discussed. Finally, the present research status, challenges, and future research opportunities of self-adaptive bulk/surface engineered BixOyBrz are prospected. It is anticipated that this critical review can trigger deeper investigations and attract upcoming innovative ideas on the rational design of BixOyBrz-based photocatalysts.
    Ultralow Ag-assisted carbon-carbon coupling mechanism on Cu-based catalysts for electrocatalytic CO2 reduction
    Lei Xue, Qi-Yuan Fan, Yuansong Zhao, Yang Liu, Heng Zhang, Min Sun, Yan Wang, Shanghong Zeng
    2023, 82(7): 414-422.  DOI: 10.1016/j.jechem.2023.04.005
    Abstract ( 9 )   PDF (10773KB) ( 6 )  
    Electrocatalytic CO2 reduction to C2H4 supplies an economically viable route for CO2 fixation with the integration of intermittent renewable energy. Cu-based catalysts are capable of catalyzing CO2 to C2H4, while suffering from the high overpotential and low Faradaic efficiency. In this joint experimental-computational work, an Ag-assisted carbon-carbon coupling is exploited on Cu-based catalysts. A systematic characterization analysis suggests that an ultralow quantity of Ag atoms in the Cu catalysts motivates electron transfer from Cu to Ag, regulating the electronic state of highly dispersed Ag. Meanwhile, the Ag incorporation provokes the formation of more oxygen defects on the catalyst surface, improving the adsorption and activation of CO2 molecules. Density functional theory studies prove the improvement effect of Ag for CO2 to COOH*. *CO hydrogenation is energetically more favorable than *CO dimerization pathway, and two *CHO dimerization produces *OCHCHO* key intermediates, which greatly reduces the energy barrier for C2H4 formation.
    Understanding of the charge storage mechanism of MnO2-based aqueous zinc-ion batteries: Reaction processes and regulation strategies
    Nan Zhang, Yu-Rui Ji, Jian-Cang Wang, Peng-Fei Wang, Yan-Rong Zhu, Ting-Feng Yi
    2023, 82(7): 423-463.  DOI: 10.1016/j.jechem.2023.03.052
    Abstract ( 9 )   PDF (53060KB) ( 4 )  
    Though secondary aqueous Zn ion batteries (AZIBs) have been received broad concern in recent years, the development of suitable cathode materials of AZIBs is still a big challenge. The MnO2 has been deemed as one of most hopeful cathode materials of AZIBs on account of some extraordinary merits, such as richly natural resources, low toxicity, high discharge potential, and large theoretical capacity. However, the crystal structure diversity of MnO2 results in an obvious various of charge storage mechanisms, which can cause great differences in electrochemical performance. Furthermore, several challenges, including intrinsic poor conductivity, dissolution of manganese and sluggish ion transport dynamics should be conquered before real practice. This work focuses on the reaction mechanisms and recent progress of MnO2-based materials of AZIBs. In this review, a detailed review of the reaction mechanisms and optimal ways for enhancing electrochemical performance for MnO2-based materials is proposed. At last, a number of viewpoints on challenges, future development direction, and foreground of MnO2-based materials of aqueous zinc ions batteries are put forward. This review clarifies reaction mechanism of MnO2-based materials of AZIBs, and offers a new perspective for the future invention in MnO2-based cathode materials, thus accelerate the extensive development and commercialization practice of aqueous zinc ions batteries.
    High-frequency supercapacitors with phosphorus-doped Ketjen black
    Qing Jin, Mahima Khandelwal, Woong Kim
    2023, 82(7): 464-474.  DOI: 10.1016/j.jechem.2023.03.041
    Abstract ( 12 )   PDF (12693KB) ( 2 )  
    Compact supercapacitors (SCs) have attracted attention for their great potential to replace bulky aluminum electrolytic capacitors (AECs) in alternating current (AC) line filtering applications. Herein, the fabrication of a high-frequency SC is reported using Ketjen black (KB) nanoparticles doped with phosphorus (P) to achieve a high areal capacitance of up to 2.26 mF cm-2 along with a high-rate capability, with a phase angle of -80.2° at 120 Hz. The high performance of the phosphorus-doped KB (designated PKB) SC with a 6 M KOH aqueous electrolyte is associated with its increased surface wettability and additional capacitive sites provided by the P-doping. Density functional theory (DFT) calculations further indicate that the P-doping enhances the interactions between the electrolyte ions and the carbon surface, thus leading to an improved electrochemical performance. These results suggest that the P-doped carbon-based SC could be highly favored in replacing conventional AECs in various high-frequency electronic devices.
    Synthesizing an inorganic-rich solid electrolyte interphase by tailoring solvent chemistry in carbonate electrolyte for enabling high-voltage lithium metal batteries
    Qiwen Ran, Hongyuan Zhao, Jintao Liu, Lei Li, Qiang Hu, Fuquan Nie, Xingquan Liu, Sridhar Kormarneni
    2023, 82(7): 475-483.  DOI: 10.1016/j.jechem.2023.03.009
    Abstract ( 10 )   PDF (11671KB) ( 5 )  
    High-voltage (>4.0 V) lithium metal battery (LBM) is considered to be one of the most promising candidates for next-generation high-energy batteries. However, the commercial carbonate electrolyte delivers a poor compatibility with Li metal anode, and its organic dominated solid electrolyte interphase (SEI) shows a low interfacial energy and a slow Li+ diffusion ability. In this work, an inorganic LiF-Li3N rich SEI is designed to enable high-voltage LBM by introducing nano-cubic LiF and LiNO3 into 1 M LiPF6 ethylene carbonate (EC)/dimethyl carbonate (DMC) (v:v = 1:1) electrolyte. Specifically, the unique nano-cubic structure of as-synthetized LiF particles achieves its high concentration dissolution in carbonate electrolyte to enhance the interfacial energy of SEI. In addition, tetramethylene sulfolane (TMS) is used as a carrier solvent to dissolve LiNO3 in the carbonate electrolyte, thereby deriving a Li3N-rich SEI. As a result, the as-designed electrolyte shows a high average Li plating/striping CE of 98.3% after 100 cycles at 0.5 mA cm-2/0.5 mA h cm-2. Furthermore, it also enables the ultrathin Li (∼50 μm) ‖LiNi0.8Co0.1Mn0.1O2 (NCM, 4.4 mA h cm-2) full cell to deliver a high-capacity retention of 80.4% after 100 cycles with an outstanding average CE of 99.7%. Notably, the practical application prospect of the modified electrolyte is also estimated in LiNi0.8Co0.1Mn0.1O2‖Li pouch cell with an energy density of 261.2 W h kg-1. This work sheds light on the internal mechanism of Li+ transport within the inorganic dominated SEI and provides a simple approach to stabilize the high-voltage LMBs.
    Bimetallic Ni-Co MOF@PAN modified electrospun separator enhances high-performance lithium-sulfur batteries
    Xiaolong Leng, Jie Zeng, Mingdai Yang, Changping Li, S.V. Prabhakar Vattikuti, Jielin Chen, Shuang Li, Jaesool Shim, Tong Guo, Tae Jo Ko
    2023, 82(7): 484-496.  DOI: 10.1016/j.jechem.2023.03.017
    Abstract ( 14 )   PDF (19066KB) ( 8 )  
    Lithium-sulfur (Li-S) batteries with high energy density are considered promising energy storage devices for the next generation. Nevertheless, the shuttle effect and the passive layer between the separator and the electrodes still seriously affect the cycle stability and life. Herein, a bimetallic Ni-Co metal-organic framework (MOF) with adsorption and catalytic synergism for polysulfides was successfully synthesized as an electrospinning separator sandwich for Li-S batteries. Introducing porous Ni-Co MOF coatings into the separator provides more adsorption catalytic sites for polysulfides, prevents their diffusion to the anode, and enhances sulfur utilization. Consequently, the improved Li-S batteries with a Ni-Co MOF@PAN (NCMP) electrospun separator delivered excellent rate performance and outstanding cycle stability, yielding an ultra-high initial capacity of 1560 mA h g-1 at 0.1 C. Notably, remarkable Li-S battery performance with a discharge capacity of 794 mA h g-1 (84.1% capacity retention) was obtained after 500 cycles, while delivering a low capacity decay rate of 0.032% during long-term cycling (up to 500 cycles) at 1 C. Surprisingly, even at the current density of 2 C, the capacity attenuation rate of 2000 cycles is only 0.034% per cycle. In addition, compared with the Celgard separator, the NCMP separator also had high thermal stability (keeping the separator outline at 200 °C) that ensured battery safety and excellent electrolyte wettability (73% porosity and 535% electrolyte absorption) and significantly enhanced the ionic conductivity and Li+ transfer number, and protected the surface integrity of the anode.
    Dynamic reconstructuring of CuS/SnO2-S for promoting CO2 electroreduction to formate
    Tong Dou, Jinqing He, Shuteng Diao, Yiping Wang, Xuhui Zhao, Fazhi Zhang, Xiaodong Lei
    2023, 82(7): 497-506.  DOI: 10.1016/j.jechem.2023.03.016
    Abstract ( 14 )   PDF (11718KB) ( 6 )  
    As the “emission peak and carbon neutrality peak” are proceeding all over the world, CO2 electroreduction is studied extensively as it is a powerful way to transform CO2 into value-added products. The earth-abundant Sn-based materials and copper sulfides as electrochemical catalysts have shown activity for generating formate from CO2 electroreduction. Herein, the composite of CuS and S-doped SnO2 (CuS/SnO2-S) was synthesized by a redox reaction under room temperature. The unique structural reconstruction of CuS/SnO2-S nanoparticles to Cu/Sn/Cu6.26Sn5 nanowires decreases the energy barrier of the adsorption of CO2, and increases the adsorption of *H, primarily suppressing the competing reaction of hydrogen evolution reaction (HER). As a result, at - 0.8 V vs. RHE, it reaches an electrochemical CO2-to-formate conversion with a Faradaic efficiency (FE) of 84.9% at a yield of 8860 µmol h-1 cm-2 under a partial current density of ∼18.8 mA cm-2 in an H-type reactor. This study provides significant insight into the structural evolution of the CuSn sulfides and the mechanism of formate formation.
    Premature deposition of lithium polysulfide in lithium-sulfur batteries
    Zi-Xian Chen, Yu-Tong Zhang, Chen-Xi Bi, Meng Zhao, Rui Zhang, Bo-Quan Li, Jia-Qi Huang
    2023, 82(7): 507-512.  DOI: 10.1016/j.jechem.2023.03.015
    Abstract ( 6 )   PDF (4913KB) ( 3 )  
    Lithium-sulfur (Li-S) batteries have attracted extensive attention due to ultrahigh theoretical energy density of 2600 Wh kg-1. Liquid-solid deposition from dissolved lithium polysulfides (LiPSs) to solid lithium sulfide (Li2S) largely determines the actual battery performances. Herein, a premature liquid-solid deposition process of LiPSs is revealed at higher thermodynamic potential than Li2S deposition in Li-S batteries. The premature solid deposit exhibits higher chemical state and hemispherical morphology in comparison with Li2S, and the premature deposition process is slower in kinetics and higher in deposition dimension. Accordingly, a supersaturation deposition mechanism is proposed to rationalize the above findings based on thermodynamic simulation. This work demonstrates a unique premature liquid-solid deposition process of Li-S batteries.
    Low-strain Co-free Li-rich layered cathode with excellent voltage and capacity stability
    Zhuo Yao, Yong Chen, Chenyu Liu, Hao Chen, Shuxing Wu, Dong Luo, Zhan Lin, Shanqing Zhang
    2023, 82(7): 513-520.  DOI: 10.1016/j.jechem.2023.03.021
    Abstract ( 13 )   PDF (8579KB) ( 16 )  
    Owing to the inherent advantages of low cost and high capacity, cobalt (Co)-free lithium (Li)-rich layered oxides have become one of the most promising cathodes for next-generation high-energy lithium-ion batteries. However, these familial cathodes suffer from serious voltage decay due to many reasons, such as oxygen release and transition metal (TM) migration, which are closely related to nanoscale strain evolution. Here, by combining the synergistic effects of surface integration, bulk doping, and concentration gradient, we successfully construct a Co-free Li-rich layered cathode with a very small volumetric strain (1.05%) between 2.0 and 4.8 V, approaching the critical value of zero strain. Various characterizations indicate that the constructed zero-strain cathode can significantly suppress the TM migration, interfacial reactions, and structural degradation including cracks, lattice defects, phase evolution, and nanovoids, leading to improved voltage stability of Co-free Li-rich layered oxides during the prolonged cycles. This work provides a strategy to eliminate the lattice strain of Li-rich layered cathodes and facilitates the up-scaled application of the as-prepared cathode materials.
    Multi-time scale identification of key kinetic processes for lithium-ion batteries considering variable characteristic frequency
    Haotian Shi, Shunli Wang, Jianhong Liang, Paul Takyi-Aninakwa, Xiao Yang, Carlos Fernandez, Liping Wang
    2023, 82(7): 521-536.  DOI: 10.1016/j.jechem.2023.02.022
    Abstract ( 20 )   PDF (4459KB) ( 3 )  
    The electrification of vehicles puts forward higher requirements for the power management efficiency of integrated battery management systems as the primary or sole energy supply. In this paper, an efficient adaptive multi-time scale identification strategy is proposed to achieve high-fidelity modeling of complex kinetic processes inside the battery. More specifically, a second-order equivalent circuit model network considering variable characteristic frequency is constructed based on the high-frequency, medium-high-frequency, and low-frequency characteristics of the key kinetic processes. Then, two coupled sub-filters are developed based on forgetting factor recursive least squares and extended Kalman filtering methods and decoupled by the corresponding time-scale information. The coupled iterative calculation of the two sub-filter modules at different time scales is realized by the voltage response of the kinetic diffusion process. In addition, the driver of the low-frequency subalgorithm with the state of charge variation amount as the kernel is designed to realize the adaptive identification of the kinetic diffusion process parameters. Finally, the concept of dynamical parameter entropy is introduced and advocated to verify the physical meaning of the kinetic parameters. The experimental results under three operating conditions show that the mean absolute error and root-mean-square error metrics of the proposed strategy for voltage tracking can be limited to 13 and 16 mV, respectively. Additionally, from the entropy calculation results, the proposed method can reduce the dispersion of parameter identification results by a maximum of 40.72% and 70.05%, respectively, compared with the traditional fixed characteristic frequency algorithms. The proposed method paves the way for the subsequent development of adaptive state estimators and efficient embedded applications.
    Defective layered Mn-based cathode materials with excellent performance via ion exchange for Li-ion batteries
    Yongheng Si, Kun Bai, Yaxin Wang, Han Lu, Litong Liu, Ziyan Long, Yujuan Zhao
    2023, 82(7): 537-546.  DOI: 10.1016/j.jechem.2023.03.035
    Abstract ( 5 )   PDF (13451KB) ( 2 )  
    Defective layered Mn-based materials were synthesized by Li/Na ion exchange to improve their electrochemical activity and Coulombic efficiency. The annealing temperature of the Na precursors was important to control the P3-P2 phase transition, which directly affected the structure and electrochemical characteristics of the final products obtained by ion exchange. The O3-Li0.78[Li0.25Fe0.075Mn0.675]Oδ cathode made from a P3-type precursor calcined at 700 °C was analyzed using X-ray photoelectron spectrometry and electron paramagnetic resonance. The results showed that the presence of abundant trivalent manganese and defects resulted in a discharge capacity of 230 mAh/g with an initial Coulombic efficiency of about 109%. Afterward, galvanostatic intermittent titration was performed to examine the Li+ ion diffusion coefficients, which affected the reversible capacity. First principles calculations suggested that the charge redistribution induced by oxygen vacancies (OVs) greatly affected the local Mn coordination environment and enhanced the structural activity. Moreover, the Li-deficient cathode was a perfect match for the pre-lithiation anode, providing a novel approach to improve the initial Coulombic efficiency and activity of Mn-based materials in the commercial application.
    Tuning the atomic configuration environment of MnN4 sites by Co cooperation for efficient oxygen reduction
    Jing Wang, Haihong Zhong, Jun Yang, Huiyu Li, Pinggui Tang, Yongjun Feng, Dianqing Li
    2023, 82(7): 547-559.  DOI: 10.1016/j.jechem.2023.04.010
    Abstract ( 8 )   PDF (3104KB) ( 9 )  
    Carbon-based N-coordinated Mn (Mn-Nx/C) single-atom electrocatalysts are considered as one of the most desirable non-precious oxygen reduction reaction (ORR) candidates due to their insignificant Fenton reactivity, high abundance, and intriguing electrocatalytic performance. However, current Mn-Nx/C single-atom electrocatalysts suffer from high overpotentials because of their low intrinsic activity and unsatisfactory chemical stability. Herein, through an in-situ polymerization-assisted pyrolysis, the Co as a second metal is introduced into the Mn-Nx/C system to construct Co, Mn-Nx dual-metallic sites, which atomically disperse in N-doped 1D carbon nanorods, denoted as Co, Mn-N/CNR and hereafter. Using electron microscopy and X-ray absorption spectroscopy (XAS) techniques, we verify the uniform dispersion of CoN4 and MnN4 atomic sites and confirm the effect of Co doping on the MnN4 electronic structure. Density functional theory (DFT) calculations further elucidate that the energy barrier of rate-determining step (*OH desorption) decreases over the 2 N-bridged MnCoN6 moieties related to the pure MnN4. This work provides an effective strategy to modulate the local coordination environment and electronic structure of MnN4 active sites for improving their ORR activity and stability.
    Electrochemical partial reduction of Ni(OH)2 to Ni(OH)2/Ni via coupled oxidation of an interfacing NiAl intermetallic compound for robust hydrogen evolution
    Young Hwa Yun, Kwangsoo Kim, Changsoo Lee, Byeong-Seon An, Ji Hee Kwon, Sechan Lee, MinJoong Kim, Jongsu Seo, Jong Hyeok Park, Byung-Hyun Kim, Hyun-Seok Cho
    2023, 82(7): 560-571.  DOI: 10.1016/j.jechem.2023.03.023
    Abstract ( 12 )   PDF (9357KB) ( 2 )  
    Ni-based porous electrocatalysts have been widely used in the hydrogen evolution reaction (HER) in alkaline water electrolysis, and the catalysts are produced by selective leaching of Al from Ni-Al alloys. It is well known that chemical leaching of Ni-Al intermetallic compound (IMC) generates a high surface area in Ni(OH)2. However, the Ni(OH)2 produced by leaching the Ni-Al intermetallic compound retards the hydrogen evolution reaction, which is attributed to its weak hydrogen adsorption energy. In this study, we controlled the chemical state of Ni using plasma vapor deposition (PVD) followed by heat treatment, selective Al leaching, and electrochemical reduction. X-ray diffraction (XRD), scanning microscopy (SEM), transmission electron microscopy (TEM), and energy-dispersive X-ray spectroscopy (EDS) were used to confirm the phase evolution of the electrocatalysts during fabrication. We reveal that the heat-treated Ni-Al alloy with a thick Ni2Al3 surface layer underwent selective Al leaching and produced biphasic interfaces comprising Ni(OH)2 and NiAl IMCs at the edges of the grains in the outermost surface layer. Coupled oxidation of the interfacing NiAl IMCs facilitated the partial reduction of Ni(OH)2 to Ni(OH)2/Ni in the grains during electrochemical reduction, as confirmed by X-ray photoelectron spectroscopy (XPS). An electrocatalyst containing partially reduced Ni(OH)2/Ni exhibited an overpotential of 54 mV at 10 mA/cm2 in a half-cell measurement, and a cell voltage of 1.675 V at 0.4 A/cm2 for single-cell operation. A combined experimental and theoretical study (density functional theory calculations) revealed that the superior HER activity was attributed to the presence of partially reduced metallic Ni with various defects and residual Al, which facilitated water adsorption, dissociation, and finally hydrogen evolution.
    Simultaneously mastering operando strain and reconstruction effects via phase-segregation strategy for enhanced oxygen-evolving electrocatalysis
    Daqin Guan, Chenliang Shi, Hengyue Xu, Yuxing Gu, Jian Zhong, Yuchen Sha, Zhiwei Hud, Meng Ni, Zongping Shao
    2023, 82(7): 572-580.  DOI: 10.1016/j.jechem.2023.03.033
    Abstract ( 29 )   PDF (7806KB) ( 19 )  
    Material strain and reconstruction effects are critical for catalysis reactions, but current insights into operando strain effects during reaction and means to master catalyst reconstruction are still lacking. Here, we propose a facile thermal-induced phase-segregation strategy to simultaneously master material operando strain and reconstruction effects for enhanced oxygen-evolving reaction (OER). Specifically, self-assembled and controllable layered LiCoO2 phase and Co3O4 spinel can be generated from pristine Li2Co2O4 spinel via Li and O volatilization under different temperatures, realizing controllable proportions of two phases by calcination temperature. Combined operando and ex-situ characterizations reveal that obvious tensile strain along (003) plane appears on layered LixCoO2 phase during OER, while low-valence Co3O4 phase transforms into high-valence CoOOHx, realizing simultaneous operando strain and reconstruction effects. Further experimental and computational investigations demonstrate that both strained LixCoO2 phase and reconstructed CoOOHx compound contribute to the beneficial adsorption of important OH- reactants, while respective roles in activity and stability are uncovered by exploring their lattice-oxygen participation mechanism. This work not only reveals material operando strain effects during OER, but also inaugurates a new thermal-induced phase-segregation strategy to artificially master material operando strain and reconstruction effects, which will enlighten rational material design for many potential reactions and applications.
    Three-in-one LaNiO3 functionalized separator boosting electrochemical stability and redox kinetics for high-performance Li-S battery
    Weiyu Wang, Mingxiu Hou, Fangqian Han, Di Yu, Jie Liu, Qian Zhang, Fengli Yu, Lei Wang, Maoshuai He
    2023, 82(7): 581-591.  DOI: 10.1016/j.jechem.2023.03.046
    Abstract ( 8 )   PDF (3003KB) ( 2 )  
    The lithium-sulfur (Li-S) battery, as one of the energy storage devices, has been in the limelight due to its high theoretical energy density. However, the poor redox kinetics and the “shuttle effect” of polysulfides severely restrict the use of Li-S batteries in practical applications. Herein, a novel bimetallic LaNiO3 functional material with high electrical conductivity and catalytic property is prepared to act as a high-efficiency polysulfide shuttling stopper. The three LaNiO3 samples with different physical/chemical characteristics are obtained by controlling the calcination temperature. In conjunction with the high electrical conductivity and excellent catalytic properties of the as-prepared materials, the appropriate chemisorption toward polysulfides offers great potential to enhance electrochemical stability for high-performance Li-S batteries. Particularly, the Li-S cell with the separator modified by such functional material gives a specific capacity of 658 mA h g-1 after 500 cycles at a high current density of 2 C. Even with high sulfur loading of 6.05 mg cm-2, the Li-S battery still exhibits an areal specific capacity of 2.81 mA h cm-2 after 150 cycles. This work paves a new avenue for the rational design of materials for separator modification in high-performance Li-S batteries.
    An overview of deep eutectic solvents: Alternative for organic electrolytes, aqueous systems & ionic liquids for electrochemical energy storage
    Akshay Sharma, Renuka Sharma, Ramesh C. Thakur, Lakhveer Singh
    2023, 82(7): 592-626.  DOI: 10.1016/j.jechem.2023.03.039
    Abstract ( 11 )   PDF (16213KB) ( 3 )  
    As the demand for sustainable energy sources continues to rise, the need for efficient and reliable energy storage systems becomes crucial. In order to effectively store and distribute renewable energy, new and innovative solutions must be explored. This review examines the deep eutectic solvents (DESs) as a green, safe, and affordable solution for the electrochemical energy storage and conversion field, offering tremendous opportunities and a promising future. DESs are a class of environment-friendly solvents known for their low toxicity and unique properties, such as their good conductivity, high thermal stability, and non-flammability. This review explores the fundamentals, preparations, and various interactions that often predominate in the formation of DESs, the properties of DESs, and how DESs are better than traditional solvents involving cost-ineffective and unsafe organic electrolytes and ionic liquids as well as inefficient aqueous systems due to low energy density for electrochemical energy storage applications. Then, a particular focus is placed on the various electrochemical applications of DESs, including their role in the electrolytes in batteries/supercapacitors, electropolishing and electrodeposition of metals, synthesis of electrode materials, recycling of electrodes, and their potential for use in CO2 capture. The review concludes by exploring the challenges, research gaps, and future potential of DESs in electrochemical applications, providing a comprehensive overview, and highlighting key considerations for their design and use.
    Platinum quantum dots-decorated MXene-derived titanium dioxide nanowire/Ti3C2 heterostructure for use in solar-driven gas-phase carbon dioxide reduction to yield value-added fuels
    Kamakshaiah Charyulu Devarayapalli, S.V. Prabhakar Vattikuti, Dong Jin Kim, Youngsu Lim, Bolam Kim, Gyuhyeon Kim, Dae Sung Lee
    2023, 82(7): 627-637.  DOI: 10.1016/j.jechem.2023.03.034
    Abstract ( 8 )   PDF (9067KB) ( 5 )  
    Solar-driven photocatalytic CO2 reduction to produce valuable chemicals and fuels offers an attractive strategy in alleviating the energy crisis. Pt quantum dots (PtQDs) with TiO2 nanowire (TiO2NW)/Ti3C2 MXene heterostructures (Pt-TiO2NW/Ti3C2) with tight interfacial contacts between the various components were prepared at room temperature via oxidation reactions. The incorporated PtQDs played crucial roles as electron conduction bridges supported by the cocatalyst effect, effectively enhancing the separation efficiencies of photoinduced electron/hole pairs and improving CO2 reduction under simulated solar light irradiation. The Pt-TiO2NW/Ti3C2 heterostructures exhibited remarkable carbon monoxide (CO) and methane (CH4) production at respective rates of 38.14 and 36.15 μmol g-1 after 10 h of simulated solar light irradiation, an apparent quantum yield of 1.68%, and 79.2% selectivity for CH4. The photocatalytic activities of the Pt-TiO2NW/Ti3C2 heterostructures for CO2 reduction were significantly enhanced compared to those of TiO2NW/Ti3C2 and the single-component photocatalysts, and they exhibited remarkable stabilities even after five cycles. In addition, the densities of states and electronic characteristics of Ti3C2 MXene and Pt-TiO2NW/Ti3C2 were studied using density functional theory, and a synergistic mechanism of the improvement in CO2 photoreduction is proposed.
    Visible light-induced synthesis of biomass-derived quinoxaline by using Co phthalocyanine immobilized on pyridine-doped g-C3N4
    Mingren Jin, Seyed Mohsen Sadeghzadeh, Jinzhu Chen
    2023, 82(7): 638-652.  DOI: 10.1016/j.jechem.2023.04.013
    Abstract ( 7 )   PDF (16436KB) ( 2 )  
    Visible light-driven valorization of biomass has recently been a pioneering field for nitrogen-containing heterocyclics syntheses due to its sustainable features. Herein, various aromatic ring-doped g-C3N4 nanosheets (Ar-g-C3N4; Ar = Py, Pm, Ph) were precisely designed to modulate their intrinsic electronic and band structure, which involves pyridine (Py), pyrimidine (Pm), and benzene (Ph)-doped g-C3N4. Photocatalysts (CoPc/Ar-g-C3N4) of cobalt(II) phthalocyanine (CoPc)-fabricated Ar-g-C3N4 were then developed for oxidative cyclization of furoin with 1,2-phenylenediamines for syntheses of various biomass-derived quinoxalines under visible-light irradiation. The catalytic activity (in terms of TOFs) of serial CoPc/Ar-g-C3N4 samples increased with their transient photocurrents with CoPc/Py-g-C3N4 as the most active one. For CoPc/Py-g-C3N4, CoPc species functioned as both sensitizer and catalytic sites; while, doped Py led to a narrowed bandgap energy. Mechanism research further demonstrated that O2 was activated to superoxide radical (O2-) by photoexcited high-level-energy electron (HLEE) transfer from Py-g-C3N4 to CoPc for the subsequent aerobic oxidation.