# High-efficiency femtosecond laser fabrication of graphene-hybrid planar micro-supercapacitors with micro/nanostructured electrodes

**Authors:** Yuyuan Zhang, Tingting Zou, Haobo Jiang, Xiuyan Fu, Wei Xin, Yiyang Meng, Xilin Li, Jun-Ming Cao, Lin Yang, Yuanzheng Li, Weizhen Liu, Dongdong Han, Xing-Long Wu, Jianjun Yang, Haiyang Xu, Yichun Liu

PMC · DOI: 10.1038/s41377-025-02182-5 · Light, Science & Applications · 2026-01-21

## TL;DR

A new method uses laser technology to create efficient micro-supercapacitors with graphene, promising better performance for flexible electronics.

## Contribution

A universal fabrication strategy using femtosecond laser plasma lithography with spatial light modulation for high-efficiency micro-supercapacitors.

## Key findings

- The method achieves sub-wavelength micro/nanostructured electrodes with high device density and processing efficiency.
- Optimized devices show specific capacitance of ~41.4 F cm−3 and 93% retention over 5000 cycles.
- The technology supports applications in flexible sensors and compact power supplies.

## Abstract

The integration of surface-regular micro/nanostructured electrodes within a limited footprint area is promising to enhance the electrochemical performance of planar micro-supercapacitors (P-MSCs), while developing simple yet efficient manufacturing methods for such electrodes remains a challenge. Here, we propose a universal strategy combining femtosecond laser plasma lithography with spatial light modulation (SLM-FPL), fabricating well-ordered sub-wavelength micro/nanostructured electrodes of interdigital P-MSCs (SEP-MSCs) on graphene oxide (GO) films. Achieving 500/50 µm finger widths/spacings and 680 nm internal grating periods, this method enables device densities >25 units inch−2 with processing efficiency orders of magnitude higher than conventional laser direct writing. Further performance optimizations via wettability modification, electric field engineering, and hybrid composites (GO-MXene/COF) yield outstanding specific capacitance (~41.4 F cm−3) and cycling stability (93% retention over 5000 cycles), supporting applications in flexible sensors and compact power supplies. This SLM-FPL technology shows strong potential for high-performance, spatially efficient SEP-MSCs in next-generation integrated systems.

Universal femtosecond laser and spatial light modulation enable rapid fabrication of graphene-hybrid micro-supercapacitors on silicon. Simultaneous formation of ordered subwavelength electrode micro/nanostructures boosts processing efficiency and device performance.

## Full-text entities

- **Chemicals:** GO (MESH:C000628730), MXene (MESH:C000723374), graphene (MESH:D006108), COF (MESH:C043212)

## Full text

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## Figures

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Source: https://tomesphere.com/paper/PMC12819388