Microheater with Copper Nanofiber Network Via Electrospinning and Electroless Deposition

Overview

Journal Sci Rep

Specialty Science

Date 2023 Dec 14

PMID 38097668

Authors

Na Kyoung Kim

Kanghyun Kim

Hansol Jang

Taechang An

Hyun-Joon Shin

Geon Hwee Kim

Affiliations

Soon will be listed here.

Abstract

In this report, we present the development of a copper nanofiber network-based microheater, designed for applications in electron microscopes, gas sensing, and cell culture platforms. The seed layer, essential for electroless deposition, was fabricated through the electrospinning of a palladium-contained polyvinylpyrrolidone solution followed by a heat treatment. This process minimized the contact resistance between nanofibers. We successfully fabricated a microheater with evenly distributed temperature by controlling the electrospinning time, heat treatment conditions, and electroless deposition time. We assessed the electrical and thermal characteristics of the microheater by examining the nanofiber density, sheet resistance, and transmittance. The microheater's performance was evaluated by applying current, and we verified its capacity to heat up to a maximum of 350 °C. We further observed the microheater's temperature distribution at varying current levels through an infrared camera. The entire manufacturing procedure takes place under normal pressure, eliminating the need for masking or etching processes. This renders the method easily adaptable to the mass production of microdevices. The method is expected to be applicable to various materials and sizes and is cost-effective compared to commercially produced microheaters developed through microelectromechanical system processes, which demand complex facilities and high cost.

Citing Articles

Fabrication of Oil-Absorbing Porous Sponges via 3D Electrospinning of Recycled Expanded Polystyrene with Functional Additive.

Kim T, Kang S, Kim K, Kim G Polymers (Basel). 2024; 16(23).

PMID: 39684067 PMC: 11644678. DOI: 10.3390/polym16233322.

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