A Novel Strategy to Build Functional Filler Networks by Combining Silver Nanoparticle In-situ Formation, Optimized Barrier Height and Volume Excluding Effect

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Abstract

The fabrication of high-performance functional polymer composites requires delicate balance between functionalities, filler content and overall performance, and new preparation route is urgently needed. Guided by Simmons theory, a PDMS-based stretchable conductor with metal-level conductivity is realized through a novel strategy by combining silver nanoparticle in-situ formation, optimized barrier height and volume excluding effect. Firstly, a universal matrix-independent etching-reduction method generates uniform Ag nanoparticles (Ag NPs, ~9.7 nm), shortening tunneling distances. Then, tunneling barrier height is minimized to 0.06 eV by aligning energy levels of surface-treated silver nanoflakes (AgFs) and PDMS, reducing electron scattering. Finally, silver-plated PDMS (PAg) microspheres act as volume-excluding phase, compressing tunneling widths below the critical threshold (<10 nm). This integrated approach yields exceptional electrical conductivity (29429 S/cm) at 50 wt% Ag loading. Such tunneling networks retain 53% conductivity at 100% strain, while thermal conductivity increases from 4.3 to 24.3 W/m·K. This work demonstrates rational quantum tunneling barrier control to overcome performance trade-offs, providing a design framework for advanced conductive composites.

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