posted on 2023-03-02, 13:34authored byKang Ji, Sisi Li, Yong Lin, Jiaxue Zhang, Menglu Wang, Chong Bai, Desheng Kong
The rise of stretchable electronics
calls for deformable
forms
of rechargeable batteries as compatible power sources. The crumpled
electrode design is a promising avenue for stretchable batteries by
providing sufficient internal space to accommodate tensile deformations.
Current electrodes typically have rough surfaces with visible corrugations,
which present practical challenges in assembling compact cells for
wearable systems. In this study, we report the design and preparation
of ultrastretchable electrodes with microwrinkled surface textures.
Crumpled electrodes are created in a transfer-printing process based
on active materials deposited on metal film current collectors. A
polymer membrane is introduced as a key mechanical support to effectively
enhance the durability of these electrodes against large and repetitive
tensile strains. A stretchable pouch cell of Zn-MnO2 rechargeable
battery is constructed with a total thickness of ∼1 mm. The
battery cell demonstrates a high specific capacity of 211 mAh g–1, stable charge–discharge cycling performances,
and ultrahigh deformability of up to 525% strain. The compact design
allows the battery to achieve conformal attachment to the skin and
versatile integration with various deformable systems. The present
work offers a generic approach to creating highly stretchable batteries
with microwrinkled electrodes.