Laser-Engineered Interfacial Dielectrophoresis-Aligned Nanowire Networks for Transparent Electromagnetic Interference-Shielding Films.
Jungang Zhang, Venkatarao Selamneni, Bhavani Prasad Yalagala, Benjamin King, Jiaoran Wang, Luvsanbat Khurelbaatar, Carlos García Núñez, Mahmoud Wagih, Morteza Amjadi, Hadi Heidari
Abstract
Open AccessNanowires (NW) hold substantial promise for high-performance electronics; however, the lack of programmable, deterministic control and alignment strategies limits their seamless integration onto flexible target substrates, posing challenges to manufacturing reliability, efficiency, and scalability. Herein, we propose a scalable and adaptable interfacial dielectrophoresis (i-DEP) method for precise translational and rotational (0-150°) manipulation of NWs on thin polymer films. A subsequent noncontact picosecond laser post-treatment is introduced to effectively enhance electrical and optical properties by welding NW junctions through controlled thermal diffusion and localized-field confinement. The laser-welded silver nanowires (AgNW) network has attained ∼46× reduction in sheet resistance and a 10% enhancement in transmittance. The i-DEP aligned, laser-treated ultrathin AgNW/polyimide film achieves 35 dB electromagnetic interference shielding effectiveness, demonstrating over 1000× improvement compared to randomly oriented drop-cast AgNW networks. The additional shielding contribution arises from the capacitively coupled interwire network in the predefined aligned-NWs structure, realizing performance beyond that attainable by conductivity alone. This work presents a laser-engineered, i-DEP-aligned NW network that reinforces interfacial NW network quality and provides a systematic fabrication and optimization strategy for advancing wireless, flexible, and high-performance transparent electronic devices.