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Wan-Yue Diao Dan Xie Yan-Fei Li Ru Jiang Fang-Yu Tao Prof. Hai-Zhu Sun Prof. Xing-Long Wu Dr. Xiao-Ying Zhang Prof. Jing-Ping Zhang 《Chemistry (Weinheim an der Bergstrasse, Germany)》2021,27(31):8168-8177
Lithium metal anodes (LMAs) with high energy density have recently captured increasing attention for development of next-generation batteries. However, practical viability of LMAs is hindered by the uncontrolled Li dendrite growth and infinite dimension change. Even though constructing 3D conductive skeleton has been regarded as a reliable strategy to prepare stable and low volume stress LMAs, engineering the renewable and lithiophilic conductive scaffold is still a challenge. Herein, a robust conductive scaffold derived from renewable cellulose paper, which is coated with reduced graphene oxide and decorated with lithiophilic Au nanoparticles, is engineered for LMAs. The graphene cellulose fibres with high surface area can reduce the local current density, while the well-dispersed Au nanoparticles can serve as lithiophilic nanoseeds to lower the nucleation overpotential of Li plating. The coupled relationship can guarantee uniform Li nucleation and unique spherical Li growth into 3D carbon matrix. Moreover, the natural cellulose paper possesses outstanding mechanical strength to tolerate the volume stress. In virtue of the modulated deposition behaviour and near-zero volume change, the hybrid LMAs can achieve reversible Li plating/stripping even at an ultrahigh current density of 10 mA cm−2 as evidenced by high Coulombic efficiency (97.2 % after 60 cycles) and ultralong lifespan (1000 cycles) together with ultralow overpotential (25 mV). Therefore, this strategy sheds light on a scalable approach to multiscale design versatile Li host, promising highly stable Li metal batteries to be feasible and practical. 相似文献
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Dr. Yao-Yao Wang Dr. Hong-Hong Fan Zhi-Wei Wang Wan-Yue Diao Dr. Chao-Ying Fan Prof. Xing-Long Wu Prof. Jing-Ping Zhang 《Chemistry (Weinheim an der Bergstrasse, Germany)》2019,25(66):15173-15181
Owing to low ion/electron conductivity and large volume change, transitional metal dichalcogenides (TMDs) suffer from inferior cycle stability and rate capability when used as the anode of lithium-ion batteries (LIBs). To overcome these disadvantages, amorphous molybdenum sulfide (MoSx) nanospheres were prepared and coated with an ultrathin carbon layer through a simple one-pot reaction. Combining X-ray photoelectron spectroscopy (XPS) with theoretical calculations, MoSx was confirmed as having a special chain molecular structure with two forms of S bonding (S2− and S22−), the optimal adsorption sites of Li+ were located at S22−. As a result, the MoSx electrode exhibits superior cycle and rate capacities compared with crystalline 2H-MoS2 (e.g., delivering a high capacity of 612.4 mAh g−1 after 500 cycles at 1 A g−1). This is mainly attributed to more exposed active S22− sites for Li storage, more Li+ transfer pathways for improved ion conductivity, and suppressed electrode structure pulverization of MoSx derived from the inherent chain-like molecular structure. Quantitative charge storage analysis further demonstrates the improved pseudocapacitive contribution of amorphous MoSx induced by fast reaction kinetics. Moreover, the morphology contrast after cycling demonstrates the dispersion of active materials is more uniform for MoSx than 2H-MoS2, suggesting the MoSx can well accommodate the volume stress of the electrode during discharging. Through regulating the molecular structure, this work provides an effective targeted strategy to overcome the intrinsic issues of TMDs for high-performance LIBs. 相似文献
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Dan Xie Huan-Huan Li Yan-Hong Shi Wan-Yue Diao Ru Jiang Prof. Hai-Zhu Sun Prof. Xing-Long Wu Dr. Wenliang Li Dr. Chao-Ying Fan Prof. Jing-Ping Zhang 《Chemistry (Weinheim an der Bergstrasse, Germany)》2020,26(4):853-862
The Fe-based transition metal oxides are promising anode candidates for lithium storage considering their high specific capacity, low cost, and environmental compatibility. However, the poor electron/ion conductivity and significant volume stress limit their cycle and rate performances. Furthermore, the phenomena of capacity rise and sudden decay for α-Fe2O3 have appeared in most reports. Here, a uniform micro/nano α-Fe2O3 nanoaggregate conformably enclosed in an ultrathin N-doped carbon network (denoted as M/N-α-Fe2O3@NC) is designed. The M/N porous balls combine the merits of secondary nanoparticles to shorten the Li+ transportation pathways as well as alleviating volume expansion, and primary microballs to stabilize the electrode/electrolyte interface. Furthermore, the ultrathin carbon shell favors fast electron transfer and protects the electrode from electrolyte corrosion. Therefore, the M/N-α-Fe2O3@NC electrode delivers an excellent reversible capacity of 901 mA h g−1 with capacity retention up to 94.0 % after 200 cycles at 0.2 A g−1. Notably, the capacity rise does not happen during cycling. Moreover, the lithium storage mechanism is elucidated by ex situ XRD and HRTEM experiments. It is verified that the reversible phase transformation of α↔γ occurs during the first cycle, whereas only the α-Fe2O3 phase is reversibly transformed during subsequent cycles. This study offers a simple and scalable strategy for the practical application of high-performance Fe2O3 electrodes. 相似文献
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Yao-Yao Wang Wan-Yue Diao Dr. Chao-Ying Fan Prof. Xing-Long Wu Prof. Jing-Ping Zhang 《Chemistry (Weinheim an der Bergstrasse, Germany)》2019,25(38):8975-8981
Lithium-ion batteries (LIBs) are one of the most significant energy storage devices applied in power supply facilities. However, a huge number of spent LIBs would bring harmful resource waste and environmental hazards. In this study, a benign hydrometallurgical method using phytic acid as precipitant is proposed to recover useful metallic Mn ions from spent LiMn2O4 batteries. Besides Mn-based cathodes, this recovery process is also applicable for other commercial batteries. More importantly, for the first time, the as-obtained manganous complex is employed as a nanofiller in a polyethylene oxide matrix to largely improve Li+ conductivity and transference number. As a result, when applied in all-solid-state lithium batteries, high capacity and outstanding cyclic stability are achieved with capacity retention of 86.4 % after 60 cycles at 0.1 C. The recovery of spent lithium batteries not only has benefits for the environment and resources, but also shows great potential application in all-solid-state lithium batteries, which opens up a costless and efficient circulation pathway for clean and reliable energy storage systems. 相似文献
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滑石粉的主要化学成分是Mg3[Si_4010](OH)_2,通过检测面粉中~(24)Mg和~(28)Si原子核的含量,可以计算出面粉中滑石粉的含量.利用中子活化分析方法测量面粉中~(24)Mg和~(28)Si原子核的含量问题时,被测样品内部中子通量和能量随厚度的变化以及γ射线自吸收效应会对测量结果有较大的影响.利用MCNP5 (Monte Carlo N-particle transport code system 5)模拟了中子通量和能量与样品厚度变化的关系,并利用氦3正比计数管测量样品不同厚度处中子通量,结果显示MCNP5模拟结果与实验测量结果基本相符.通过MCNP5模拟和碘化钠探测器测量,研究了γ射线自吸收效应与样品厚度的关系,确定了6.6 cm的样品厚度为最佳实验条件,根据模拟结果给出了特征γ射线计数与样品厚度的关系式,并与实验进行对比,结果符合得较好. 相似文献
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International Journal of Theoretical Physics - In this paper, we lock the focus in effect of $\mathcal {P}\mathcal {T}$ -symmetric operation on the dynamics of concurrence and the first-order... 相似文献
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Dan Xie Yuan Sang Dan-Hong Wang Wan-Yue Diao Fang-Yu Tao Chang Liu Prof. Jia-Wei Wang Prof. Hai-Zhu Sun Prof. Jing-Ping Zhang Prof. Xing-Long Wu 《Angewandte Chemie (International ed. in English)》2023,62(7):e202216934
Uncontrolled dendrites growth and serious parasitic reactions in aqueous electrolytes, greatly hinder the practical application of aqueous zinc-ion battery. On the basis of in situ-chemical construction and performance-improving mechanism, multifunctional fluoroethylene carbonate (FEC) is introduced into aqueous electrolyte to construct a high-quality and ZnF2-riched inorganic/organic hybrid SEI (ZHS) layer on Zn metal anode (ZMA) surface. Notably, FEC additive can regulate the solvated structure of Zn2+ to reduce H2O molecules reactivity. Additionally, the ZHS layer with strong Zn2+ affinity can avoid dendrites formation and hinder the direct contact between the electrolyte and anode. Therefore, the dendrites growth, Zn corrosion, and H2 evolution reaction on ZMA in FEC-included ZnSO4 electrolyte are highly suppressed. Thus, ZMA in such electrolyte realize a long cycle life over 1000 h and deliver a stable coulombic efficiency of 99.1 % after 500 cycles. 相似文献
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