Litcius/Paper detail

One‐Step Preparation of Ethyl Cellulose Films with Asymmetric Graded Pores for Low Dielectric Printing Substrates

Fukun Niu, Ru Song, Rong Yu, Yibo Zhang, Yuheng Fu, Yuanjin Zeng, Longxiang Zhan, Zhuqun Shi, Chuanxi Xiong, Quanling Yang

2025Advanced Materials6 citationsDOI

Abstract

Abstract The innovation of communication technology and the proliferation of the Internet of Things have propelled the exploitation and application of mid‐to‐low end and disposable radio frequency devices, alongside the development of low dielectric materials. Traditional petroleum‐based low dielectric substrates, led by polyimide, present several challenges, including higher cost, non‐renewability, difficulty in disposal and recycling, rendering them unsuitable for disposable applications. In this study, the asymmetric ethyl cellulose (EC) porous film with dense skins is prepared in one step by the evaporation process of EC/ethanol/H 2 O solution. The synergistic pore‐forming mechanism of the dry phase inversion technique and breath figure phenomenon is proposed based on EC pore morphology. The relative permittivity of the asymmetric EC porous film is 2.02 ± 0.03 (6 GHz), demonstrating satisfactory dielectric stability, printing adaptability, and bending ability. The EC in discarded printed antennas and remnants from the film‐making process can be separated and recovered through a simple dissolution and centrifugation process. The green and simple preparation process, extremely low manufacturing cost, excellent recyclability, and potential roll‐to‐roll process adaptability make asymmetric EC porous film highly competitive in the mid‐to‐low end and disposable centimetre wave radio frequency device substrate fields.

Topics & Concepts

Materials scienceEthyl celluloseDielectricPorosityDissolutionMicrocrystalline celluloseChemical engineeringInkjet printingComposite materialOptoelectronicsNanotechnologySubstrate (aquarium)Phase inversionCarboxymethyl cellulosePorous mediumScreen printingCellulosePrinted electronicsPermittivityRadio frequencyEvaporation3D printingHalideSolution processMicrostructureThin filmRadio-frequency identificationPolystyreneGelatinAdvanced Cellulose Research StudiesAdvanced Antenna and Metasurface TechnologiesSynthesis and properties of polymers
One‐Step Preparation of Ethyl Cellulose Films with Asymmetric Graded Pores for Low Dielectric Printing Substrates | Litcius