Author
Listed:
- Sumin Kang
(Seoul National University of Science and Technology)
- Jaehyeock Chang
(Korea Advanced Institute of Science and Technology)
- Jaeseung Lim
(Korea Institute of Machinery and Materials
University of Science and Technology)
- Dong Jun Kim
(Korea Advanced Institute of Science and Technology)
- Taek-Soo Kim
(Korea Advanced Institute of Science and Technology)
- Kyung Cheol Choi
(Korea Advanced Institute of Science and Technology)
- Jae Hak Lee
(Korea Institute of Machinery and Materials)
- Seungman Kim
(Korea Institute of Machinery and Materials
University of Science and Technology
Texas A&M University)
Abstract
Laser lift-off (LLO) of ultrathin polyimide (PI) films is important in the manufacturing of ultrathin displays. However, conventional LLO technologies face challenges in separating the ultrathin PI films without causing mechanical and electrical damage to integrated devices. Here, we propose a graphene-enabled laser lift-off (GLLO) method to address the challenges. The GLLO method is developed by integrating chemical vapor deposition (CVD)-grown graphene at the interface between a transparent carrier and an ultrathin PI film, exhibiting improved processability and lift-off quality. In particular, the GLLO method significantly mitigates plastic deformation of the PI film and minimizes carbonaceous residues remaining on the carrier. The role of graphene is attributed to three factors: enhancement of interfacial UV absorption, lateral heat diffusion, and adhesion reduction, and experimentations and numerical simulations verify the mechanism. Finally, it is demonstrated that the GLLO method separates ultrathin organic light-emitting diode (OLED) devices without compromising performance. We believe that this work will pave the way for utilizing CVD graphene in various laser-based manufacturing applications.
Suggested Citation
Sumin Kang & Jaehyeock Chang & Jaeseung Lim & Dong Jun Kim & Taek-Soo Kim & Kyung Cheol Choi & Jae Hak Lee & Seungman Kim, 2024.
"Graphene-enabled laser lift-off for ultrathin displays,"
Nature Communications, Nature, vol. 15(1), pages 1-10, December.
Handle:
RePEc:nat:natcom:v:15:y:2024:i:1:d:10.1038_s41467-024-52661-3
DOI: 10.1038/s41467-024-52661-3
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