In-Depth Study of Laser Diode Ablation of Kapton Polyimide for Flexible Conductive Substrates
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Romero Maldonado, Francisco Javier; Salinas Castillo, Alfonso; Rivadeneyra Torres, Almudena; Albrecht, Andreas; Godoy Medina, Andrés; Morales Santos, Diego Pedro; Rodríguez Santiago, NoelEditorial
MDPI
Materia
Laser-induced graphene Polyimide Flexible electronics Laser-scribing Sheet resistance Contact resistance
Date
2018-07-11Referencia bibliográfica
Romero, F.J. [et al.]. In-Depth Study of Laser Diode Ablation of Kapton Polyimide for Flexible Conductive Substrates. Nanomaterials 2018, 8, 517; doi:10.3390/nano8070517.
Sponsorship
This work has been partially supported by the Spanish Ministry of Education, Culture and Sport (MECD), the European Union and the University of Granada through the project TEC2017-89955-P, the pre-doctoral grant FPU16/01451, the fellowship H2020-MSCA-IF-2017 794885-SELFSENS and the grant “Initiation to Research”. Additionally, this work was supported by the German Research Foundation (DFG) and the Technical University of Munich within the Open Access Publishing Funding Programme.Abstract
This work presents a detailed study of the photothermal ablation of KaptonR polyimide
by a laser diode targeting its electrical conductivity enhancement. Laser-treated samples were
structurally characterized using Scanning Electron Microscopy (SEM), Raman spectroscopy, X-ray
Photoelectron Spectroscopy (XPS), as well as Diffuse Reflectance Infrared Fourier Transform (DRIFT)
spectroscopy. The results show that the laser-assisted ablation constitutes a simple one-step and
environmental friendly method to induce graphene-derived structures on the surface of polyimide
films. The laser-modified surface was also electrically characterized through the Transmission Line
Method (TLM) aiming at the improvement of the conductivity of the samples by tuning the laser
power and the extraction of the contact resistance of the electrodes. Once the laser-ablation process is
optimized, the samples increase their conductivity up to six orders of magnitude, being comparable
to that of graphene obtained by chemical vapor deposition or by the reduction of graphene-oxide.
Additionally, we show that the contact resistance can be decreased down to promising values of
~2 W when using silver-based electrodes.