Literature DB >> 23575691

Graphene-modified LiFePO₄ cathode for lithium ion battery beyond theoretical capacity.

By Lung-Hao Hu1, Feng-Yu Wu, Cheng-Te Lin, Andrei N Khlobystov, Lain-Jong Li.   

Abstract

The specific capacity of commercially available cathode carbon-coated lithium iron phosphate is typically 120-160 mAh g(-1), which is lower than the theoretical value 170 mAh g(-1). Here we report that the carbon-coated lithium iron phosphate, surface-modified with 2 wt% of the electrochemically exfoliated graphene layers, is able to reach 208 mAh g(-1) in specific capacity. The excess capacity is attributed to the reversible reduction-oxidation reaction between the lithium ions of the electrolyte and the exfoliated graphene flakes, where the graphene flakes exhibit a capacity higher than 2,000 mAh g(-1). The highly conductive graphene flakes wrapping around carbon-coated lithium iron phosphate also assist the electron migration during the charge/discharge processes, diminishing the irreversible capacity at the first cycle and leading to ~100% coulombic efficiency without fading at various C-rates. Such a simple and scalable approach may also be applied to other cathode systems, boosting up the capacity for various Li batteries.

Entities:  

Year:  2013        PMID: 23575691     DOI: 10.1038/ncomms2705

Source DB:  PubMed          Journal:  Nat Commun        ISSN: 2041-1723            Impact factor:   14.919


  8 in total

1.  Room-temperature single-phase Li insertion/extraction in nanoscale Li(x)FePO4.

Authors:  Pierre Gibot; Montse Casas-Cabanas; Lydia Laffont; Stephane Levasseur; Philippe Carlach; Stéphane Hamelet; Jean-Marie Tarascon; Christian Masquelier
Journal:  Nat Mater       Date:  2008-07-27       Impact factor: 43.841

2.  The design of a LiFePO4/carbon nanocomposite with a core-shell structure and its synthesis by an in situ polymerization restriction method.

Authors:  Yonggang Wang; Yarong Wang; Eiji Hosono; Kaixue Wang; Haoshen Zhou
Journal:  Angew Chem Int Ed Engl       Date:  2008       Impact factor: 15.336

3.  High-quality thin graphene films from fast electrochemical exfoliation.

Authors:  Ching-Yuan Su; Ang-Yu Lu; Yanping Xu; Fu-Rong Chen; Andrei N Khlobystov; Lain-Jong Li
Journal:  ACS Nano       Date:  2011-02-10       Impact factor: 15.881

4.  Electronically conductive phospho-olivines as lithium storage electrodes.

Authors:  Sung-Yoon Chung; Jason T Bloking; Yet-Ming Chiang
Journal:  Nat Mater       Date:  2002-10       Impact factor: 43.841

5.  A multifunctional 3.5 V iron-based phosphate cathode for rechargeable batteries.

Authors:  B L Ellis; W R M Makahnouk; Y Makimura; K Toghill; L F Nazar
Journal:  Nat Mater       Date:  2007-09-09       Impact factor: 43.841

6.  Aluminium-doped LiFePO4 single crystals. Part II. Ionic conductivity, diffusivity and defect model.

Authors:  Ruhul Amin; Chengtian Lin; Joachim Maier
Journal:  Phys Chem Chem Phys       Date:  2008-04-17       Impact factor: 3.676

7.  Nano-network electronic conduction in iron and nickel olivine phosphates.

Authors:  P Subramanya Herle; B Ellis; N Coombs; L F Nazar
Journal:  Nat Mater       Date:  2004-02-22       Impact factor: 43.841

8.  Lithium deintercalation in LiFePO4 nanoparticles via a domino-cascade model.

Authors:  C Delmas; M Maccario; L Croguennec; F Le Cras; F Weill
Journal:  Nat Mater       Date:  2008-07-20       Impact factor: 43.841
  8 in total
  20 in total

1.  Fabrication of Nb2O5 nanosheets for high-rate lithium ion storage applications.

Authors:  Meinan Liu; Cheng Yan; Yuegang Zhang
Journal:  Sci Rep       Date:  2015-02-09       Impact factor: 4.379

2.  Eco-friendly nitrogen-containing carbon encapsulated LiMn2O4 cathodes to enhance the electrochemical properties in rechargeable Li-ion batteries.

Authors:  P Robert Ilango; K Prasanna; Su Jung Do; Yong Nam Jo; Chang Woo Lee
Journal:  Sci Rep       Date:  2016-07-13       Impact factor: 4.379

3.  Towards High Capacity Li-ion Batteries Based on Silicon-Graphene Composite Anodes and Sub-micron V-doped LiFePO4 Cathodes.

Authors:  M J Loveridge; M J Lain; I D Johnson; A Roberts; S D Beattie; R Dashwood; J A Darr; R Bhagat
Journal:  Sci Rep       Date:  2016-11-29       Impact factor: 4.379

4.  Artificial solid electrolyte interphase for aqueous lithium energy storage systems.

Authors:  Jian Zhi; Alireza Zehtab Yazdi; Gayathri Valappil; Jessica Haime; Pu Chen
Journal:  Sci Adv       Date:  2017-09-08       Impact factor: 14.136

Review 5.  Synthesis of graphene-transition metal oxide hybrid nanoparticles and their application in various fields.

Authors:  Arpita Jana; Elke Scheer; Sebastian Polarz
Journal:  Beilstein J Nanotechnol       Date:  2017-03-24       Impact factor: 3.649

6.  Redox-Active Separators for Lithium-Ion Batteries.

Authors:  Zhaohui Wang; Ruijun Pan; Changqing Ruan; Kristina Edström; Maria Strømme; Leif Nyholm
Journal:  Adv Sci (Weinh)       Date:  2017-12-19       Impact factor: 16.806

Review 7.  Composites of Graphene and LiFePO4 as Cathode Materials for Lithium-Ion Battery: A Mini-review.

Authors:  Haixia Wu; Qinjiao Liu; Shouwu Guo
Journal:  Nanomicro Lett       Date:  2014-09-27

8.  A phytic acid derived LiMn0.5Fe0.5PO4/Carbon composite of high energy density for lithium rechargeable batteries.

Authors:  Yan Meng; Yujue Wang; Zhaokun Zhang; Xiaojuan Chen; Yong Guo; Dan Xiao
Journal:  Sci Rep       Date:  2019-04-30       Impact factor: 4.379

9.  Low-Temperature Thermally Reduced Molybdenum Disulfide as a Pt-Free Counter Electrode for Dye-Sensitized Solar Cells.

Authors:  Che-Hsien Lin; Chuen-Horng Tsai; Fan-Gang Tseng; Yang-Yen Yu; Hsuan-Chung Wu; Chien-Kuo Hsieh
Journal:  Nanoscale Res Lett       Date:  2015-11-17       Impact factor: 4.703

10.  Manipulating size of Li3V2(PO4)3 with reduced graphene oxide: towards high-performance composite cathode for lithium ion batteries.

Authors:  Xianjun Zhu; Zan Yan; Wenyan Wu; Wencong Zeng; Yuanxin Du; Yu Zhong; Haidie Zhai; Hengxing Ji; Yanwu Zhu
Journal:  Sci Rep       Date:  2014-08-29       Impact factor: 4.379
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