Journal of Applied Electrochemistry

, Volume 49, Issue 3, pp 271–280 | Cite as

Building thermally stable supercapacitors using temperature-responsive separators

  • Han Jiang
  • Robert K. Emmett
  • Mark E. RobertsEmail author
Research Article


Thermal runaway is posing big threat towards common electrochemical devices, such as lithium ion batteries and supercapacitors. It is caused by heat accumulated within electrochemical device and can cause devices to lose functionality, shorten service-life, or even cause hazardous fires and explosions. One effective approach to tackle thermal runaway is to break the electrochemical reaction Arrhenius thermal loop by introducing reaction inhibiting components into the system. Herein, through facile wet casting method, a temperature responsive polymer, poly(N-isopropylacrylamide) (PNIPAM) was cast into thin film and sandwiched in between polypropylene (PP) to make into a temperature responsive separator. It was found that once the temperature rose to 70 °C, instead of increasing in capacitance like in the control, PNIPAM-included batches decreased in capacitance. This capacitance reduction was mainly contributed by increased charge transfer resistance, which was caused by the sol–gel transition and precipitating PNIPAM chains residing upon PP membrane. A similar capacitance reduction was also observed for the ferricyanide redox system. Further investigation also revealed thicker PNIPAM films exhibited enhanced capacitance reduction and scan rate dependency. Temperature responsive polymer separators may prove to be an effective method to suppress high temperature electrochemical reactions and thus offer promise to reversible, thermally stabilized electrochemical devices.

Graphical Abstract


Stimuli-responsive materials PNIPAM Separator Sol–gel transition Temperature dependent properties Supercapacitor 



The authors would like to thank George Wetzel and Kim Ivey at advanced materials research lab for the helps of characterizations and department of materials science and engineering, department of chemical and biomolecular engineering of Clemson University for funding support.

Supplementary material

10800_2018_1278_MOESM1_ESM.pdf (447 kb)
Supplementary material 1 (PDF 446 KB)


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Copyright information

© Springer Nature B.V. 2019

Authors and Affiliations

  1. 1.Department of Materials Science and EngineeringClemson UniversityClemsonUSA
  2. 2.Department of Chemical & Biomolecular EngineeringClemson UniversityClemsonUSA

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