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1,320 results on '"Hwang, Bing-Joe"'

1. Rechargeable Li/Cl$_2$ battery down to -80 {\deg}C

Author

Liang, Peng, Zhu, Guanzhou, Huang, Cheng-Liang, Li, Yuan-Yao, Sun, Hao, Yuan, Bin, Wu, Shu-Chi, Li, Jiachen, Wang, Feifei, Hwang, Bing-Joe, and Dai, Hongjie

Subjects
Physics - Applied Physics
Abstract

Low temperature rechargeable batteries are important to life in cold climates, polar/deep-sea expeditions and space explorations. Here, we report ~ 3.5 - 4 V rechargeable lithium/chlorine (Li/Cl2) batteries operating down to -80 {\deg}C, employing Li metal negative electrode, a novel CO2 activated porous carbon (KJCO2) as the positive electrode, and a high ionic conductivity (~ 5 to 20 mS cm-1 from -80 {\deg}C to 25 {\deg}C) electrolyte comprised of 1 M aluminum chloride (AlCl3), 0.95 M lithium chloride (LiCl), and 0.05 M lithium bis(fluorosulfonyl)imide (LiFSI) in low melting point (-104.5 {\deg}C) thionyl chloride (SOCl2). Between room-temperature and -80 {\deg}C, the Li/Cl2 battery delivered up to ~ 30,000 - 4,500 mAh g-1 first discharge capacity and a 1,200 - 5,000 mAh g-1 reversible capacity (discharge voltages in ~ 3.5 to 3.1 V) over up to 130 charge-discharge cycles. Mass spectrometry and X-ray photoelectron spectroscopy (XPS) probed Cl2 trapped in the porous carbon upon LiCl electro-oxidation during charging. At lower temperature down to -80 {\deg}C, SCl2/S2Cl2 and Cl2 generated by electro-oxidation in the charging step were trapped in porous KJCO2 carbon, allowing for reversible reduction to afford a high discharge voltage plateau near ~ 4 V with up to ~ 1000 mAh g-1 capacity for SCl2/S2Cl2 reduction and up to ~ 4000 mAh g-1 capacity at ~ 3.1 V plateau for Cl2 reduction. Towards practical use, we made CR2032 Li/Cl2 battery cells to drive digital watches at -40 {\deg}C and light emitting diode at -80 {\deg}C, opening Li/Cl2 secondary batteries for ultra-cold conditions.

Published
2023

2. Shedding Light on Rechargeable Na/Cl$_2$ Battery

Author

Zhu, Guanzhou, Liang, Peng, Huang, Cheng-Liang, Wu, Shu-Chi, Huang, Cheng-Chia, Li, Yuan-Yao, Jiang, Shi-Kai, Huang, Wei-Hsiang, Li, Jiachen, Wang, Feifei, Hwang, Bing-Joe, and Dai, Hongjie

Subjects
Physics - Applied Physics
Abstract

Advancing new ideas of rechargeable batteries represents an important path to meeting the ever increasing energy storage needs. Recently we showed rechargeable sodium/chlorine (Na/Cl$_2$) (or lithium/chlorine Li/Cl$_2$) batteries that used a Na (or Li) metal negative electrode, a microporous amorphous carbon nanosphere (aCNS) positive electrode and an electrolyte containing dissolved AlCl$_3$ and fluoride additives in thionyl chloride (SOCl$_2$). The main battery redox reaction involved conversion between NaCl and Cl$_2$ trapped in the carbon positive electrode, delivering a cyclable capacity of up to 1200 mAh g$^{-1}$ (based on positive electrode mass) at a ~ 3.5 V discharge voltage. Here, we discovered by X-ray photoelectron spectroscopy (XPS) that upon charging a Na/Cl$_2$ battery, chlorination of carbon in the positive electrode occurred to form C-Cl accompanied by molecular Cl$_2$ infiltrating the porous aCNS, consistent with Cl$_2$ probed by mass spectrometry. Synchrotron X-ray diffraction observed the development of graphitic ordering in the initially amorphous aCNS under battery charging when the carbon matrix was oxidized/chlorinated and infiltrated with Cl$_2$. The C-Cl, Cl$_2$ species and graphitic ordering were reversible upon discharge, accompanied by NaCl formation. The results revealed redox conversion between NaCl and Cl$_2$, reversible graphitic ordering/amorphourization of carbon through battery charge/discharge, and for the first time probed trapped Cl$_2$ in porous carbon by XPS., Comment: 30 pages, 9 figures

Published
2023

4. High-Capacity Rechargeable $Li/Cl_2$ Batteries with Graphite Positive Electrodes

Author

Zhu, Guanzhou, Liang, Peng, Huang, Cheng-Liang, Huang, Cheng-Chia, Li, Yuan-Yao, Wu, Shu-Chi, Li, Jiachen, Wang, Feifei, Tian, Xin, Huang, Wei-Hsiang, Jiang, Shi-Kai, Hung, Wei-Hsuan, Chen, Hui, Lin, Meng-Chang, Hwang, Bing-Joe, and Dai, Hongjie

Subjects
Physics - Applied Physics
Abstract

Developing new types of high-capacity and high-energy density rechargeable battery is important to future generations of consumer electronics, electric vehicles, and mass energy storage applications. Recently we reported ~ 3.5 V sodium/chlorine $(Na/Cl_2)$ and lithium/chlorine $(Li/Cl_2)$ batteries with up to 1200 mAh $g^{-1}$ reversible capacity, using either a Na or Li metal as the negative electrode, an amorphous carbon nanosphere (aCNS) as the positive electrode, and aluminum chloride $(AlCl_3)$ dissolved in thionyl chloride $(SOCl_2)$ with fluoride-based additives as the electrolyte. The high surface area and large pore volume of aCNS in the positive electrode facilitated NaCl or LiCl deposition and trapping of $Cl_2$ for reversible $NaCl/Cl_2$ or $LiCl/Cl_2$ redox reactions and battery discharge/charge cycling. Here we report an initially low surface area/porosity graphite (DGr) material as the positive electrode in a $Li/Cl_2$ battery, attaining high battery performance after activation in carbon dioxide $(CO_2)$ at 1000 {\deg}C (DGr_ac) with the first discharge capacity ~ 1910 mAh $g^{-1}$ and a cycling capacity up to 1200 mAh $g^{-1}$. Ex situ Raman spectroscopy and X-ray diffraction (XRD) revealed the evolution of graphite over battery cycling, including intercalation/de-intercalation and exfoliation that generated sufficient pores for hosting $LiCl/Cl_2$ redox. This work opens up widely available, low-cost graphitic materials for high-capacity alkali metal/$Cl_2$ batteries. Lastly, we employed mass spectrometry to probe the $Cl_2$ trapped in the graphitic positive electrode, shedding light into the $Li/Cl_2$ battery operation., Comment: 37 pages, 16 figures, 1 table

Published
2022

16. Multiple protective layers for suppressing Li dendrite growth and improving the cycle life of anode-free lithium metal batteries

Author

Merso, Semaw Kebede, Tekaligne, Teshager Mekonnen, Adigo Weret, Misganaw, Shitaw, Kassie Nigus, Nikodimos, Yosef, Yang, Sheng-Chiang, Muche, Zabish Bilew, Taklu, Bereket Woldegbreal, Hotasi, Boas Tua, Chang, Chia-Yu, Jiang, Shi-Kai, Brunklaus, Gunther, Winter, Martin, Wu, She-Huang, Su, Wei-Nien, Mou, Chung-Yuan, and Hwang, Bing Joe

Published
2024
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30. An in-situ formed bifunctional layer for suppressing Li dendrite growth and stabilizing the solid electrolyte interphase layer of anode free lithium metal batteries

Author

Merso, Semaw Kebede, Tekaligne, Teshager Mekonnen, Weldeyohannes, Haile Hisho, Nikodimos, Yosef, Shitaw, Kassie Nigus, Jiang, Shi-Kai, Huang, Chen-Jui, Wondimkun, Zewdu Tadesse, Jote, Bikila Alemu, Wichmann, Lennart, Brunklaus, Gunther, Winter, Martin, Wu, She-Huang, Su, Wei-Nien, Mou, Chung-Yuan, and Hwang, Bing Joe

Published
2022
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44. Synergistic interfacial electronic modulation of topotactically developed bimetallic CoNiP on NiS nanorods for enhanced alkaline hydrogen evolution reaction.

Author

Dilebo, Woldesenbet Bafe, Tsai, Meng-Che, Chang, Chia-Yu, Edao, Habib Gemechu, Nikodimos, Yosef, Moges, Endalkachew Asefa, Lakshmanan, Keseven, Angerasa, Fikiru Temesgen, Guta, Chemeda Barasa, Ibrahim, Kassa Belay, Awoke, Yohannes Ayele, Alamirew, Tesfaye, Liao, Wei-Sheng, Desta, Gidey Bahre, Chen, Jeng-Lung, Su, Wei-Nien, and Hwang, Bing Joe

Published
2024
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45. Materials of Value-Added Electrolysis for Green Hydrogen Production.

Author

Moges, Endalkachew Asefa, Lakshmanan, Keseven, Chang, Chia-Yu, Liao, Wei-Sheng, Angerasa, Fikiru Temesgen, Dilebo, Woldesenbet Bafe, Edao, Habib Gemechu, Tadele, Kirubel Teshome, Alemayehu, Dessalew Dagnew, Bejena, Baru Debtera, Guta, Chemeda Barasa, Chang, Chun-Chi, Tsai, Meng-Che, Su, Wei-Nien, and Hwang, Bing Joe

Published
2024
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46. Systematic "Apple‐to‐Apple" Comparison of Single‐Crystal and Polycrystalline Ni‐Rich Cathode Active Materials: From Comparable Synthesis to Comparable Electrochemical Conditions.

Author

Lüther, Marco Joes, Jiang, Shi‐Kai, Lange, Martin Alexander, Buchmann, Julius, Gómez Martín, Aurora, Schmuch, Richard, Placke, Tobias, Hwang, Bing Joe, Winter, Martin, and Kasnatscheew, Johannes

Subjects
NANOPARTICLES, SINGLE crystals, FUSED salts, CATHODES, MORPHOLOGY
Abstract

State‐of‐the‐art ternary layered oxide cathode active materials in Li‐ion batteries (LIBs) consist of polycrystalline (PC), i.e., micron‐sized secondary particles, which in turn consist of numerous nanosized primary particles. Recent approaches to develop single crystals (SCs), i.e., single and separated micron‐sized primary particles, appear promising in terms of cycle life given their mechanical stability. However, a direct and systematic ("fair") comparison of SC with PC in LIB cell application remains a challenge due to both differences on material level and state‐of‐charge (SoC), as SCs typically have slightly lower delithiation capacities/Li+ extraction ratios. In this work, PC and SC Li[Ni0.8Mn0.1Co0.1]O2 (NMC811) are synthesized with comparable bulk and surface characteristics from identical self‐synthesized precursors. Indeed, the cycle life of SCs is not only superior, when conventionally charged to equal upper cutoff voltage (UCV), as shown in NMC||Li and NMC||graphite cells, but also after adjusting UCVs to similar SoCs, where bigger SCs counterintuitively have even a better rate performance and cycle life. [ABSTRACT FROM AUTHOR]

Published
2024
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47. Crown ether functionalized large-area graphene oxide and MXene hybridize as ion-sieving layers for high-performance lithium–sulfur batteries.

Author

Ye, Yun-Sheng, Mohamed, Mohamed Gamal, Tsai, Meng-Che, Hu, Huan-Yu, Hwang, Bing-Joe, and Kuo, Shaw-Wei

Abstract

Two crucial challenges hindering the widespread application of lithium–sulfur (Li–S) batteries are the sluggish conversion of sulfur and the shuttle of lithium polysulfides (LPSs). Designing an ion-selective membrane that allows fast Li-ion transport yet restricts the migration of LPSs via the construction of well-defined structures in a scalable and cost-effective manner is a promising strategy for advancing high-energy-density lithium–sulfur batteries. Herein, a diamino crown ether (CE) molecule is grafted to the surface of large-area graphene oxide (GO) to modify the separator in Li–S batteries using a straightforward coating method without a polymer binder. The decorated GO-CE ion-sieving layer possesses high ion conductive properties and abundant supramolecular channels created by CE functional groups, which can simultaneously chemically/physically inhibit shuttling of LPSs and catalytically accelerate the diffusion/conversion of LPSs through the CE-Li+ interaction. The GO-CE modified separator, featuring an ultra-thin (∼100 nm) and ultra-light (∼0.06 mg cm−2) ion-sieving layer, enables the cell to have excellent rate performance and good cyclic stability with a low capacity decay of 0.035% per cycle over 1500 cycles at 1C. The GO-CE is prepared to hybridize with MXene nanosheets to create a cell with an electrically and thermally conductive ion-sieving layer, exhibiting not only ultra-low capacity decay of 0.025% but also excellent resistance to thermal gradients and an intelligent self-closing mechanism at elevated temperatures. This study introduces a novel strategy for enhancing the performance of Li–S batteries using ion-sieving membranes. [ABSTRACT FROM AUTHOR]

Published
2024
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