What question did this study set out to answer?

To investigate the structural anisotropy in freestanding laser-induced graphene sheets created by defocused lasers on polyimide.

March 18, 2026Open Access

Defocused Laser-Induced Anisotropic Freestanding Graphene Architectures

Key Points

To investigate the structural anisotropy in freestanding laser-induced graphene sheets created by defocused lasers on polyimide.
Utilized a CO2 pulse laser with controlled defocusing on polyimide
Investigated structural properties using angle-resolved Raman spectroscopy
Analyzed carbon content and thickness of produced graphene structures
Produced 3D-FLIG structures approximately 29 μm thick with over 90% carbon content
Observed significant in-plane anisotropy in FLIG sheets (p < 0.0001)
Identified strain-induced symmetry breaking and preferred lattice alignment in graphene structures.

Abstract

We report the intrinsic structural anisotropy in freestanding laser-induced graphene (FLIG) sheets produced through controlled laser defocusing of a CO2 pulse laser on polyimide. Defocusing enlarges the laser spots, enabling uniform carbonization and spontaneous substrate detachment without postprocessing, resulting in 3D-FLIG structures (∼29 μm thick) and over 90% carbon content. Angle-resolved Raman spectroscopy shows significant in-plane anisotropy in FLIG sheets and LIG needles (p < 0.0001), contrasting with isotropic embedded LIG, due to strain-induced symmetry breaking and preferred lattice alignment. Laser defocusing offers a scalable way to engineer microlevel directional anisotropy in freestanding graphene for potential electronic and thermal devices.

Defocused Laser-Induced Anisotropic Freestanding Graphene Architectures

Key Points

Abstract

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