Preparation and Electrochemical Performance of 1.5 V and 3.0 V-Class Primary Film Batteries for Radio Frequency Identification (RFID)
Young-Gi Lee, Min-Gyu Choi, Kun-Young Kang, Kwang-Man Kim
J. Electrochem. Sci. Technol. 2010;1(1):39-44. DOI: https://doi.org/10.5229/JECST.2010.1.1.039
|
Citations to this article as recorded by
How to increase the potential of aqueous Zn-MnO2 batteries: The effect of pH gradient electrolyte
Ramona Dūrena, Anzelms Zukuls, Mārtiņš Vanags, Andris Šutka
Electrochimica Acta.2022; 434: 141275. CrossRef Passivation capability of carbon black layers for screen-printed battery applications with Ag current collectors
Patrick Rassek, Erich Steiner, Timothy C. Claypole, Martin Krebs, Michael Herrenbauer
Applied Physics A.2020;[Epub] CrossRef Gap width modification on fully screen-printed coplanar Zn|MnO2 batteries
Patrick Rassek, Erich Steiner, Michael Herrenbauer, Timothy C Claypole
Flexible and Printed Electronics.2020; 5(3): 035007. CrossRef
The effect of electrode calendering on the performance of fully printed Zn∣MnO
2
batteries
Patrick Rassek, Erich Steiner, Michael Herrenbauer, Timothy C Claypole
Flexible and Printed Electronics.2019; 4(3): 035003. CrossRef Cathode material for lithium ion accumulators prepared by screen printing for Smart Textile applications
T. Syrový, T. Kazda, L. Syrová, J. Vondrák, L. Kubáč, M. Sedlaříková
Journal of Power Sources.2016; 309: 192. CrossRef Flexible zinc–carbon batteries with multiwalled carbon nanotube/conductive polymer cathode matrix
Zhiqian Wang, Natalia Bramnik, Sagar Roy, Giuseppe Di Benedetto, James L. Zunino, Somenath Mitra
Journal of Power Sources.2013; 237: 210. CrossRef
|