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Author: Lu, Qiongqiong × End date: 2024 × Start date: 2020 × Start date: 1984 × DDC: 500 × Type: Text × WGL Institute: IFWD ×

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Now showing 1 - 4 of 4
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    Ultrathin positively charged electrode skin for durable anion-intercalation battery chemistries
    ([London] : Nature Publishing Group UK, 2023) Sabaghi, Davood; Wang, Zhiyong; Bhauriyal, Preeti; Lu, Qiongqiong; Morag, Ahiud; Mikhailovia, Daria; Hashemi, Payam; Li, Dongqi; Neumann, Christof; Liao, Zhongquan; Dominic, Anna Maria; Nia, Ali Shaygan; Dong, Renhao; Zschech, Ehrenfried; Turchanin, Andrey; Heine, Thomas; Yu, Minghao; Feng, Xinliang
    The anion-intercalation chemistries of graphite have the potential to construct batteries with promising energy and power breakthroughs. Here, we report the use of an ultrathin, positively charged two-dimensional poly(pyridinium salt) membrane (C2DP) as the graphite electrode skin to overcome the critical durability problem. Large-area C2DP enables the conformal coating on the graphite electrode, remarkably alleviating the electrolyte. Meanwhile, the dense face-on oriented single crystals with ultrathin thickness and cationic backbones allow C2DP with high anion-transport capability and selectivity. Such desirable anion-transport properties of C2DP prevent the cation/solvent co-intercalation into the graphite electrode and suppress the consequent structure collapse. An impressive PF6−-intercalation durability is demonstrated for the C2DP-covered graphite electrode, with capacity retention of 92.8% after 1000 cycles at 1 C and Coulombic efficiencies of > 99%. The feasibility of constructing artificial ion-regulating electrode skins with precisely customized two-dimensional polymers offers viable means to promote problematic battery chemistries.
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    Ultrathin positively charged electrode skin for durable anion-intercalation battery chemistries
    ([London] : Nature Publishing Group UK, 2023) Sabaghi, Davood; Wang, Zhiyong; Bhauriyal, Preeti; Lu, Qiongqiong; Morag, Ahiud; Mikhailovia, Daria; Hashemi, Payam; Li, Dongqi; Neumann, Christof; Liao, Zhongquan; Dominic, Anna Maria; Nia, Ali Shaygan; Dong, Renhao; Zschech, Ehrenfried; Turchanin, Andrey; Heine, Thomas; Yu, Minghao; Feng, Xinliang
    The anion-intercalation chemistries of graphite have the potential to construct batteries with promising energy and power breakthroughs. Here, we report the use of an ultrathin, positively charged two-dimensional poly(pyridinium salt) membrane (C2DP) as the graphite electrode skin to overcome the critical durability problem. Large-area C2DP enables the conformal coating on the graphite electrode, remarkably alleviating the electrolyte. Meanwhile, the dense face-on oriented single crystals with ultrathin thickness and cationic backbones allow C2DP with high anion-transport capability and selectivity. Such desirable anion-transport properties of C2DP prevent the cation/solvent co-intercalation into the graphite electrode and suppress the consequent structure collapse. An impressive PF6−-intercalation durability is demonstrated for the C2DP-covered graphite electrode, with capacity retention of 92.8% after 1000 cycles at 1 C and Coulombic efficiencies of > 99%. The feasibility of constructing artificial ion-regulating electrode skins with precisely customized two-dimensional polymers offers viable means to promote problematic battery chemistries.
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    Atomic Sn–enabled high-utilization, large-capacity, and long-life Na anode
    (Washington, DC [u.a.] : Assoc., 2022) Xu, Fei; Qu, Changzhen; Lu, Qiongqiong; Meng, Jiashen; Zhang, Xiuhai; Xu, Xiaosa; Qiu, Yuqian; Ding, Baichuan; Yang, Jiaying; Cao, Fengren; Yang, Penghui; Jiang, Guangshen; Kaskel, Stefan; Ma, Jingyuan; Li, Liang; Zhang, Xingcai; Wang, Hongqiang
    Constructing robust nucleation sites with an ultrafine size in a confined environment is essential toward simultaneously achieving superior utilization, high capacity, and long-term durability in Na metal-based energy storage, yet remains largely unexplored. Here, we report a previously unexplored design of spatially confined atomic Sn in hollow carbon spheres for homogeneous nucleation and dendrite-free growth. The designed architecture maximizes Sn utilization, prevents agglomeration, mitigates volume variation, and allows complete alloying-dealloying with high-affinity Sn as persistent nucleation sites, contrary to conventional spatially exposed large-size ones without dealloying. Thus, conformal deposition is achieved, rendering an exceptional capacity of 16 mAh cm−2 in half-cells and long cycling over 7000 hours in symmetric cells. Moreover, the well-known paradox is surmounted, delivering record-high Na utilization (e.g., 85%) and large capacity (e.g., 8 mAh cm−2) while maintaining extraordinary durability over 5000 hours, representing an important breakthrough for stabilizing Na anode.
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    Single “Swiss-roll” microelectrode elucidates the critical role of iron substitution in conversion-type oxides
    (Washington, DC [u.a.] : Assoc., 2022) Liu, Lixiang; Huang, Shaozhuan; Shi, Wujun; Sun, Xiaolei; Pang, Jinbo; Lu, Qiongqiong; Yang, Ye; Xi, Lixia; Deng, Liang; Oswald, Steffen; Yin, Yin; Liu, Lifeng; Ma, Libo; Schmidt, Oliver G.; Shi, Yumeng; Zhang, Lin
    Advancing the lithium-ion battery technology requires the understanding of electrochemical processes in electrode materials with high resolution, accuracy, and sensitivity. However, most techniques today are limited by their inability to separate the complex signals from slurry-coated composite electrodes. Here, we use a three-dimensional “Swiss-roll” microtubular electrode that is incorporated into a micrometer-sized lithium battery. This on-chip platform combines various in situ characterization techniques and precisely probes the intrinsic electrochemical properties of each active material due to the removal of unnecessary binders and additives. As an example, it helps elucidate the critical role of Fe substitution in a conversion-type NiO electrode by monitoring the evolution of Fe2O3 and solid electrolyte interphase layer. The markedly enhanced electrode performances are therefore explained. Our approach exposes a hitherto unexplored route to tracking the phase, morphology, and electrochemical evolution of electrodes in real time, allowing us to reveal information that is not accessible with bulk-level characterization techniques.