Degradation mechanisms in Li-ion batteries: a state-of-the-art review

International Journal of Energy Research

Volumn 41, Issue 14, 2017, Pages 1963-1986

  Kabir, M M ^a   Demirocak, Dervis Emre ^a  

^a Texas AandM University Kingsville   (United States)

Author keywords

characterization techniques; chemical origin; degradation causes; degradation mechanisms; Li ion batteries; mechanical origin

Indexed keywords

CHARACTERIZATION; DEGRADATION; ELECTRIC BATTERIES; ELECTROLYTES; ENERGY STORAGE; INTERCALATION; IONS; LITHIUM; MECHANISMS; SECONDARY BATTERIES; SOLID ELECTROLYTES;

CHARACTERIZATION TECHNIQUES; CHEMICAL ORIGIN; DEGRADATION MECHANISM; ENERGY STORAGE TECHNOLOGIES; MECHANICAL ORIGIN; SOLID ELECTROLYTE INTERPHASE; STATIONARY ENERGY STORAGES; VOLUMETRIC ENERGY DENSITIES;

LITHIUM-ION BATTERIES;

EID: 85018913817     PISSN: 0363907X     EISSN: 1099114X     Source Type: Journal    
DOI: 10.1002/er.3762     Document Type: Review

References (73)

1. Newton DE. Fracking: A Reference Handbook (Contemporary World Issues). Publisher: ABC-CLIO-LLC: California, 2015. ISBN:978-1-61069-691-3.
2. Chen DD, Microscopic investigations of degradation in lithium-ion batteries, Doctoral Thesis, Karlsruher Institut für Technologie (KIT), June (2012).
3. Tarascon JM, Armand M. Issues and challenges facing rechargeable lithium batteries. Nature 2001; 414:359–367.
4. Noh KW, Dillon SJ. Morphological changes in and around Sn electrodes during Li ion cycling characterized by in situ environmental TEM. Scripta Materialia 2013; 69:658–661.
5. Shen C, Wang S, Jin Y, Han WQ. In situ AFM imaging of solid electrolyte interfaces on HOPG with ethylene carbonate and fluoroethylene carbonate based electrolytes. ACS Applied Materials Interfaces 2015; 7:25441–25447.
6. Huang Z et al. Preparation, characterization, and lithium intercalation behavior of LiVO3 cathode material for lithium-ion batteries. Journal Physical Chemistry C 2016; 120(6):3242–3249.
7. Lyczko N et al. Characterization of LiFePO4/C cathode for lithium ion batteries. Industrial and Engineering Chemistry Research 2012; 51:292–300.
8. Mikolajczak C, Kahn M, White K, Thomas Long R, Lithium-ion batteries hazard and use assessment, Fire Protection Research Foundation, July (2011).
9. Srinivasan V, Batteries for vehicular applications. In: AIP conference proceedings physics of sustainable energy, Berkeley, CA, (2008), vol. 1044, pp. 283–296.
10. Nagpure SC, Bhushan B, Babu SS. Multi-scale characterization studies of aged Li-ion large format cells for improved performance: an overview. Journal of Electrochemical Society 2013; 160(11):A2111–A2154.
11. Howell D, Overview of battery R&D activities, US Department of Energy, Annual Merit Review, (2012), Washington, D.C.
12. Dunn B, Kamath H, Tarascon JM. Electrical energy storage for the grid: a battery of choices. Science 2011; 334:928–935.
13. Kong F, Kostecki R, Nadeau G, Song X, Zaghib K, Kinoshita K, McLarnon F. In-situ studies of SEI formation. Journal of Power Sources 2001; 97–98:58–66.
14. Goodenough JB. Cathode materials: a personal perspective. Journal of Power Sources 2007; 174:996.
15. Nitta N, Wu F, Lee JT, Yushin G. Li-ion battery materials: present and future. Materials Today 2015; 18:5.
16. Hellqvist Kjell M, Performance of conventional and structural lithium-ion batteries, Doctoral Thesis, Applied Electrochemistry, School of Chemical Science and Engineering, Kungliga Tekniska Högskolan, Stockholm (2013).
17. Arora P, Zhang Z. Battery separators. Chemical Reviews 2004; 104:4419–4462.
18. http://epg.eng.ox.ac.uk/content/degradation-lithium-ion-batteries, Christoph Birkl, Energy & Power Group (EPG), DepartmentofEngineeringScience, UniversityofOxford, (2014).
19. Demirocak DE, Bhushan B. Probing the aging effects on nanomechanical properties of a LiFePO4 cathode in a large format prismatic cell. Journal of Power Sources 2015; 280:256–262.
20. Arora P, White RE, Doyle M. Capacity fade mechanisms and side reactions in lithium-ion batteries. Journal of the Electrochemical Society 1998; 145:3647–3667.
21. Broussely M, Biensan P, Bonhomme F, Blanchard P, Herreyre S, Nechev K, Staniewicz RJ. Main aging mechanisms in Li ion batteries. Journal of Power Sources 2005; 146:90–96.
22. Mukhopadhyay A, Sheldon BW. Deformation and stress in electrode materials for Li-ion batteries. Progress in Materials Science 2014; 63:58–116.
23. Ramdon S, Bhushan B. Nanomechanical characterization and mechanical integrity of unaged and aged Li-ion battery cathodes. Journal of Power Sources 2014; 246:219–224.
24. Norin L, Kostecki R, McLarnon F. Study of membrane degradation in high-power lithium-ion cells. Solid-State Letters 2002; 5:A67–A69.
25. Vetter J, Novak P, Wagner MR, Veit C, Moller KC, Besenhard JO, Winter M, Wohlfahrt-Mehrens M, Vogler C, Hammouche A. Aging mechanisms in lithium-ion batteries. Journal of Power Sources 2005; 147:269–281.
26. Aurbach D, Zinigrad E, Cohen Y, Teller H. A short review of failure mechanisms of lithium metal and lithiated graphite anodes in liquid electrolyte solutions. Solid State Ionics 2002; 148:405–416.
27. Goers D, Spahr M, Leone A, Markle W, Novak P. Electrochimica Acta 2011; 56:3799.
28. Bedrov D, Smith G, Van Duin A. Journal Physical Chemical A 2012; 116:2978.
29. Marcicki J, “Modeling, parametrization, and diagnostic for lithium-ion batteries with automotive application”. Doctoral Thesis, Ohio State University, Columbus, OH, (2012).
30. Safari M, Morcrette M, Teyssot A, Delacourt C. Journal of the Electrochemical Society 2009; 156:145.
31. Ning G, White R, Popov B. Electrochimica Acta 2006; 51:2012.
32. Broussely M, Herreyre S, Biensan P, Kasztejna P, Nechev K, Staniewicz R. Journal Power Sources 2001; 97:13.
33. Ohzuku T, Ueda A, Yamamoto N, Iwakoshi Y. Journal Power Sources 1995; 54:99.
34. Ratnakumar BV, Smart MC, Surampudi S. Journal Power Sources 2001; 97–98:137.
35. Winter M, Moeller KC, Besenhard JO, Nazri GA, Pistoia G. Lithium Batteries Science and Technology. Kluwer Academic: Dordrecht, 2003.
36. Du Pasquier A, Disma F, Bowmer T, Gozdz AS, Amatucci G, Tarascon JM. Journal of the Electrochemical Society 1998; 145:472–477.
37. Spotnitz R, Franklin J. Jouranl of Power Sources 2003; 113:81–100.
38. Braithwaite JW et al. Corrosion of lithium-ion battery current collectors. Journal Electrochemical Society 1999; 146(2):448–456.
39. Wohlfahrt-Mehrens M, Vogler C, Garche J. Journal Power Sources 2004; 127:58–64.
40. Demirocak DE, Bhushan B. Journal of Colloid and Interface Science 2014; 423:151–157.
41. Zhang X, Shyy W, Sastry AM. Journal of the Electrochemical Society 2007; 154:A910–A916.
42. Christensen J, Newman J. Journal of Solid State Electrochemistry 2006; 10:293.
43. Renganathan S, Sikha G, Santhanagopalan S, White R. Journal Electrochemical Society 2010; 157:A155.
44. Zhao K, Pharr M, Vlassak J, Suo Z. Journal of Applied Physics 2010; 108:073517.
45. Deshpande R, Cheng Y, Verbrugge M, Timmons A. Journal of the Electrochemical Society 2011; 158:A718.
46. Nagpure SC, Dinwiddie R, Babu SS, Rizzoni G, Bhushan B, Frech T. Journal of Power Sources 2010; 195:872.
47. Du Pasquier A, Blyr A, Cressent A, Lenain C, Amatucci G, Tarascon JM. Journal of Power Sources 1999; 81–82:54.
48. Liu Y, Li X, Guo H, Wang Z, Hu Q, Peng W, Yang Y. Journal of Power Sources 2009; 189:721.
49. Kostecki R, Norin L, Song X, Mc Larnon F. Journal of the Electrochemical Society 2004; 151(4).
50. Spotnitz R, Ferebee M, Callahan RW, Nguyen K, Yu WC, Geiger M, Dwiggens C, Fischer H, Hoffman D, Proceedings of the 12th International Seminar on Primary and Secondary Battery Technology and Applications; Fort Lauderdale, FL, Florida Educational Seminars, Inc.: Fort Lauderdale, FL, (1995).
51. Roth EP, Doughty DH, Pile DL. Effects of separator breakdown on abuse response of 18650 Li-ion cells. Journal of Power Sources 2007; 174:579–583.
52. Maleki H, Shamsuri AK. Thermal analysis and modeling of a notebook computer battery, J. Power Sources 2003; 115:131–136.
53. Kawakita J, Kobayashi K. Journal of Power Sources 2000; 90:182.
54. Yoshimoto N, Shibata T, Ishikawa M, Morita M, Gijutu H. Journal of the Surface Finishing Society of Japan 2001; 52:581.
55. Morita M, Shibata T, Yoshimoto N, Ishikawa M. Electrochimica Acta 2002; 47:2787.
56. Morita M et al. Anodic behavior of aluminum current collector in LiTFSI solutions with different solvent compositions. Journal of Power Sources 2003; 119–121:784.
57. Cannarella J, Arnold CB. The effects of defects on localized plating in lithium-ion batteries. Journal of the Electrochemical Society 2015; 162(7):A1365–A1373.
58. Ning G, Haran B, Popov BN. Journal of Power Sources 2003; 117:160–169.
59. Dubarry M et al. Evaluation of commercial lithium-ion cells based on composite positive electrode for plug-in hybrid electric vehicle applications. Part II: Degradation mechanism under 2C cycle aging. Journal of Power Sources 2011; 196:10336–10343.
60. Ji Y, Zhang Y, Wang CY. Li-ion cell operation at low temperatures. Journal of the Electrochemical Society 2013; 160(4):A636–A649.
61. Leng F, Ming Tan C, Pecht M. Effect of temperature on the aging rate of Li ion battery operating above room temperature. Scientific Reports 2015; 5:12967. https://doi.org/10.1038/srep12967.
62. www.electropaedia.com, copyright by Woodbank Communications Ltd (2005).
63. Samadani E et al. Li-ion battery performance and degradation in electric vehicles under different usage scenarios. Intenatonal Journal Energy Research 2016; 40:379–392.
64. Karimi G, Dehghan AR. Thermal analysis of high-power lithium-ion battery packs using flow network approach. International Journal Energy Research 2014; 38:1793–1811.
65. Malik M, Dincer I, Rosen M. Review on use of phase change materials in battery thermal management for electric and hybrid electric vehicles. Internal Journal Energy Research 2016; 40:1011–1031.
66. Yamaki J, Liquid electrolytes, chapter 5, pp. 155–183, Advances in Lithium-Ion Batteries, W. van Schalkwijk and B. Scrosati (Eds.), ISBN 978-0-306-47508-5, Springer Science & Business Media New York, (2002).
67. Huang JY, Zhong L, Wang CM, Sullivan JP, Xu W, Zhang LQ, Mao SX, Hudak NS, Liu XH, Subramanian A, Fan H, Qi L, Kushima A, Li J. Science 2010; 330:1515.
68. Wang F, Yu H-C, Chen M-H, Wu L, Pereira N, Thornton K, Van DVA, Zhu Y, Amatucci GG, Graetz J. Nature Communications 2012; 3:2185.
69. Nagpure S.C., Multi-scaled characterization of aged Li-ion battery materials for improving performance, Ph.D. Thesis, The Ohio State University, Department of Mechanical and Aerospace Engineering, Columbus, Ohio (2012).
70. Nagpure SC, Bharat B, Babu SS. Multi-scale characterization studies of aged Li-ion large format cells for improved performance: an overview. Journal of Electrochemical Society 2013; 160(11):A2111–A2154.
71. Ramdon S, Bhushan B, Nagpure SC. In situ electrochemical studies of lithium-ion battery cathodes using atomic force microscopy. Journal of Power Sources 2014; 249:373–384.
72. Campana FP, Kotz R, Vetter J, Siegenthaler H. In-situ atomic force microscopy study of dimensional changes during Li+ ion intercalation/de-intercalation in highly oriented pyrolitic graphite. Electrochemistry Communition 2005; 7:107–112.
73. Park J, Kalnaus S, Han S, Lee YK, Less GB, Dudney NJ, Daniel C, Sastry AM. In situ atomic force microscope studies on lithium (de)intercalation-induced morphology changes in LixCoO2 micro-machined thin film electrodes. Journal of Power Source 2013; 222:417–425.