Literature DB >> 34158810

Designing Advanced Lithium-based Batteries for Low-temperature Conditions.

Abhay Gupta1, Arumugam Manthiram1.   

Abstract

Energy-dense rechargeable batteries have enabled a multitude of applications in recent years. Moving forward, they are expected to see increasing deployment in performance-critical areas such as electric vehicles, grid storage, space, defense, and subsea operations. While this at first glance spells great promise for conventional lithium-ion batteries, all of these use-cases, unfortunately, share periodic and recurring exposures to extremely low-temperature conditions, a performance constraint where the lithium-ion chemistry can fail to perform optimally. Next-generation chemistries employing alternative anodes with increased solvent compatibility or altogether different operating mechanisms could present an avenue for overcoming many of the low-temperature hurdles intrinsic to the lithium-ion battery. In this article, we provide a brief overview of the challenges in developing lithium-ion batteries for low-temperature use, and then introduce an array of nascent battery chemistries that may be intrinsically better suited for low-temperature conditions moving forward. Specifically, we evaluate the prospects of using lithium-metal, lithium-sulfur, and dual-ion batteries for performance-critical low-temperature applications. These three chemistries are presented as prototypical examples of how the conventional low-temperature charge-transfer resistances can be overcome. However, these three chemistries also present their own unique challenges at low temperatures, highlighting the balance between traditional low-temperature electrolyte design and next-generation approaches.

Entities:  

Keywords:  desolvation; lithium batteries; lithium-metal anode; lithium-sulfur batteries; low-temperature operation

Year:  2020        PMID: 34158810      PMCID: PMC8216142          DOI: 10.1002/aenm.202001972

Source DB:  PubMed          Journal:  Adv Energy Mater        ISSN: 1614-6832            Impact factor:   29.368


  19 in total

1.  Nonaqueous liquid electrolytes for lithium-based rechargeable batteries.

Authors:  Kang Xu
Journal:  Chem Rev       Date:  2004-10       Impact factor: 60.622

2.  Solvent-Dictated Lithium Sulfur Redox Reactions: An Operando UV-vis Spectroscopic Study.

Authors:  Qingli Zou; Yi-Chun Lu
Journal:  J Phys Chem Lett       Date:  2016-04-12       Impact factor: 6.475

3.  High-Energy Rechargeable Metallic Lithium Battery at -70 °C Enabled by a Cosolvent Electrolyte.

Authors:  Xiaoli Dong; Yuxiao Lin; Panlong Li; Yuanyuan Ma; Jianhang Huang; Duan Bin; Yonggang Wang; Yue Qi; Yongyao Xia
Journal:  Angew Chem Int Ed Engl       Date:  2019-03-26       Impact factor: 15.336

4.  Differentiating contributions to "ion transfer" barrier from interphasial resistance and Li+ desolvation at electrolyte/graphite interface.

Authors:  Kang Xu; Arthur von Cresce; Unchul Lee
Journal:  Langmuir       Date:  2010-07-06       Impact factor: 3.882

5.  Additive-Assisted Novel Dual-Salt Electrolyte Addresses Wide Temperature Operation of Lithium-Metal Batteries.

Authors:  Xuehui Shangguan; Gaojie Xu; Zili Cui; Qinglei Wang; Xiaofan Du; Kai Chen; Suqi Huang; Guofeng Jia; Faqiang Li; Xiao Wang; Di Lu; Shanmu Dong; Guanglei Cui
Journal:  Small       Date:  2019-03-08       Impact factor: 13.281

6.  Influence of Lithium Polysulfide Clustering on the Kinetics of Electrochemical Conversion in Lithium-Sulfur Batteries.

Authors:  Abhay Gupta; Amruth Bhargav; John-Paul Jones; Ratnakumar V Bugga; Arumugam Manthiram
Journal:  Chem Mater       Date:  2020-02-07       Impact factor: 9.811

7.  Wide-Temperature Electrolytes for Lithium-Ion Batteries.

Authors:  Qiuyan Li; Shuhong Jiao; Langli Luo; Michael S Ding; Jianming Zheng; Samuel S Cartmell; Chong-Min Wang; Kang Xu; Ji-Guang Zhang; Wu Xu
Journal:  ACS Appl Mater Interfaces       Date:  2017-05-30       Impact factor: 9.229

8.  Enhanced Adsorptions to Polysulfides on Graphene-Supported BN Nanosheets with Excellent Li-S Battery Performance in a Wide Temperature Range.

Authors:  Ding Rong Deng; Fei Xue; Cheng-Dong Bai; Jie Lei; Ruming Yuan; Ming Sen Zheng; Quan Feng Dong
Journal:  ACS Nano       Date:  2018-10-29       Impact factor: 15.881

9.  Distinct Nanoscale Interphases and Morphology of Lithium Metal Electrodes Operating at Low Temperatures.

Authors:  Akila C Thenuwara; Pralav P Shetty; Matthew T McDowell
Journal:  Nano Lett       Date:  2019-11-05       Impact factor: 11.189

Review 10.  A reflection on lithium-ion battery cathode chemistry.

Authors:  Arumugam Manthiram
Journal:  Nat Commun       Date:  2020-03-25       Impact factor: 14.919
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  10 in total

1.  Solvent selection criteria for temperature-resilient lithium-sulfur batteries.

Authors:  Guorui Cai; John Holoubek; Mingqian Li; Hongpeng Gao; Yijie Yin; Sicen Yu; Haodong Liu; Tod A Pascal; Ping Liu; Zheng Chen
Journal:  Proc Natl Acad Sci U S A       Date:  2022-07-05       Impact factor: 12.779

Review 2.  Active material and interphase structures governing performance in sodium and potassium ion batteries.

Authors:  Eun Jeong Kim; P Ramesh Kumar; Zachary T Gossage; Kei Kubota; Tomooki Hosaka; Ryoichi Tatara; Shinichi Komaba
Journal:  Chem Sci       Date:  2022-05-18       Impact factor: 9.969

3.  Tailoring Nitrogen Terminals on MXene Enables Fast Charging and Stable Cycling Na-Ion Batteries at Low Temperature.

Authors:  Yang Xia; Lanfang Que; Fuda Yu; Liang Deng; Zhenjin Liang; Yunshan Jiang; Meiyan Sun; Lei Zhao; Zhenbo Wang
Journal:  Nanomicro Lett       Date:  2022-07-09

Review 4.  Frontiers and Structural Engineering for Building Flexible Zinc-Air Batteries.

Authors:  Tao Zhang; Ningxiang Wu; Yanhua Zhao; Xinglong Zhang; Jiansheng Wu; Jiena Weng; Sheng Li; Fengwei Huo; Wei Huang
Journal:  Adv Sci (Weinh)       Date:  2021-12-22       Impact factor: 16.806

5.  Achieving Uniform Li Plating/Stripping at Ultrahigh Currents and Capacities by Optimizing 3D Nucleation Sites and Li2 Se-Enriched SEI.

Authors:  Jiaqi Cao; Yonghui Xie; Yang Yang; Xinghui Wang; Wangyang Li; Qiaoli Zhang; Shun Ma; Shuying Cheng; Bingan Lu
Journal:  Adv Sci (Weinh)       Date:  2022-01-24       Impact factor: 16.806

6.  Riemannian Surface on Carbon Anodes Enables Li-Ion Storage at -35 °C.

Authors:  Zongjing Lu; Jingnan Wang; Xuechun Cheng; Weiwei Xie; Zhiyi Gao; Xuejing Zhang; Yong Xu; Ding Yi; Yijun Yang; Xi Wang; Jiannian Yao
Journal:  ACS Cent Sci       Date:  2022-06-08       Impact factor: 18.728

7.  Selective Nitridation Crafted a High-Density, Carbon-Free Heterostructure Host with Built-In Electric Field for Enhanced Energy Density Li-S Batteries.

Authors:  Hongmei Wang; Yunhong Wei; Guochuan Wang; Yiran Pu; Li Yuan; Can Liu; Qian Wang; Yun Zhang; Hao Wu
Journal:  Adv Sci (Weinh)       Date:  2022-06-16       Impact factor: 17.521

8.  Operando Decoding of Surface Strain in Anode-Free Lithium Metal Batteries via Optical Fiber Sensor.

Authors:  Yanpeng Li; Yi Zhang; Zhen Li; Zhijun Yan; Xiangpeng Xiao; Xueting Liu; Jie Chen; Yue Shen; Qizhen Sun; Yunhui Huang
Journal:  Adv Sci (Weinh)       Date:  2022-07-21       Impact factor: 17.521

9.  A Universal Spinning-Coordinating Strategy to Construct Continuous Metal-Nitrogen-Carbon Heterointerface with Boosted Lithium Polysulfides Immobilization for 3D-Printed LiS Batteries.

Authors:  Yue Ouyang; Wei Zong; Xiaobo Zhu; Lulu Mo; Guojie Chao; Wei Fan; Feili Lai; Yue-E Miao; Tianxi Liu; Yan Yu
Journal:  Adv Sci (Weinh)       Date:  2022-07-21       Impact factor: 17.521

10.  A Fiber-Based 3D Lithium Host for Lean Electrolyte Lithium Metal Batteries.

Authors:  Sicen Yu; Zhaohui Wu; John Holoubek; Haodong Liu; Emma Hopkins; Yuxuan Xiao; Xing Xing; Myeong Hwan Lee; Ping Liu
Journal:  Adv Sci (Weinh)       Date:  2022-02-01       Impact factor: 16.806
  10 in total

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