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Replacing the Gallium Oxide Shell with Conductive Ag: Toward a Printable and Recyclable Composite for Highly Stretchable Electronics, Electromagnetic Shielding, and Thermal Interfaces

Abdollah Hajalilou, Elahe Parvini, Tiago A. Morgado, Pedro Alhais Lopes, M. E. Melo Jorge, Marta Freitas, Mahmoud Tavakoli

2024ACS Applied Materials & Interfaces23 citationsDOIOpen Access PDF

Abstract

and GaOOH layers around LM droplets impairs conductivity and performance. We tackle this issue by replacing the oxide layer with conductive silver (Ag) using an ultrasonic-assisted galvanic replacement reaction. The Ag-coated nanoparticles form aggregated, porous microparticles that are mixed with styrene-isoprene-styrene (SIS) polymers, resulting in a digitally printable composite with superior electrical conductivity and electromechanical properties compared to conventional fillers. Adding more LM enhances these properties further. The composite achieves EMI shielding effectiveness (SE) exceeding 75 dB in the X-band frequency range, even at 200% strain, meeting stringent military and medical standards. It is applicable in wireless communications and Bluetooth signal blocking and as a thermal interface material (TIM). Additionally, we highlight its recyclability using a biodegradable solvent, underscoring its eco-friendly potential. This composite represents a significant advancement in stretchable electronics and EMI shielding, with implications for wearable and bioelectronic applications.

Topics & Concepts

Materials scienceComposite numberElectromagnetic shieldingConductive polymerElectronicsComposite materialElectrical conductorStretchable electronicsFlexible electronicsNanotechnologyPolymerElectrical engineeringEngineeringAdvanced Sensor and Energy Harvesting MaterialsElectromagnetic wave absorption materialsDielectric materials and actuators
Replacing the Gallium Oxide Shell with Conductive Ag: Toward a Printable and Recyclable Composite for Highly Stretchable Electronics, Electromagnetic Shielding, and Thermal Interfaces | Litcius