Journal of
Mechanical Engineering Research

  • Abbreviation: J. Mech. Eng. Res.
  • Language: English
  • ISSN: 2141-2383
  • DOI: 10.5897/JMER
  • Start Year: 2009
  • Published Articles: 118

Full Length Research Paper

Development of a mathematical model to study the impact of state of charge dependent exchange current density on the generated voltage hysteresis of silicon anode-based lithium half cells

Al-Mustasin Abir Hossain
  • Al-Mustasin Abir Hossain
  • Department of Mechanical Engineering, School of Engineering and Computer Science (ENCS), Washington State University, Vancouver, WA, United States.
  • Google Scholar


  •  Received: 11 February 2021
  •  Accepted: 27 May 2021
  •  Published: 30 June 2021

References

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Hossain A, Masud N, Yasin M, Ali A (2020a). Analysis of the performance of microbial fuel cell as a potential energy storage device, International Exchange, and Innovation Conference on Engineering and Sciences (IEICES) 6 (2020) At: Kyushu University, Fukuoka City, Japan 6:149-155.
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Hossain AA (2020). Development of a physics-based mathematical model of microparticle silicon-based lithium half cells, Masters, Washington State University-Vancouver.

 

Hossain AA, Cha Y, Song M, Kim SU (2020b). Side reaction correction and non-linear exchange current density for mathematical modeling of silicon anode-based lithium-ion batteries.

 

Hossain AA, Kim SU (2020). Development of a physics-based mathematical model to analyze the limitations of microparticle silicon-based lithium half cells IMECE Technical Presentation.

 

Jin C, Li H, Song Y, Lu B, Soh A, Zhang J (2019). On stress-induced voltage hysteresis in lithium-ion batteries: Impacts of surface effects and inter-particle compression. Science China Technological Sciences 62:1357-1364.
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Li J, Dudney N, Xiao X, Cheng Y, Liang C, Verbrugge M (2014). Asymmetric rate behavior of Si anodes for lithium-ion batteries: ultrafast delithiation versus sluggish lithiation at high current densities, Advanced Energy Materials 5(6):1401627.
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Lu B, Song Y, Zhang Q, Pan J, Cheng Y, Zhang J (2016). Voltage hysteresis of lithium-ion batteries caused by mechanical stress. Physical Chemistry Chemical Physics 18(6):4721-4727.
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Song Y, Soh A, Zhang J (2016). On stress-induced voltage hysteresis in lithium ion batteries: impacts of material property, charge rate and particle size. Journal of Materials Science 51(21):9902-9911.
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Wu H, Cui Y (2012). Designing nanostructured Si anodes for high energy lithium-ion batteries. Nano Today 7(5):414-429.
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