Abstract
<jats:p> The way polymers are being designed for protection is changing. Instead of relying on heavy metals or dense composites, researchers are now creating architected polymer shields that block both electromagnetic interference (EMI) and ionizing X/γ - rays while staying light, flexible, and multifunctional. This review takes a structural view of how form dictates function. It highlights three design families that define current progress: multilayers that grade impedance and trap waves through cascaded absorption; segregated networks that build efficient conductive paths along polymer interfaces; and porous or foamed frameworks that scatter radiation through microcellular pathways, achieving strong attenuation with minimal weight. By linking architecture, filler chemistry (graphene, MXenes, ferrites, BaTiO <jats:sub>3</jats:sub> , Bi <jats:sub>2</jats:sub> O <jats:sub>3</jats:sub> , WO <jats:sub>3</jats:sub> ) and processing strategies (solution or melt mixing, magnetic alignment, additive manufacturing) to measurable outcomes—shielding effectiveness, specific efficiency, and attenuation coefficients—we show where performance gains truly come from. The review also exposes the hidden compromises between conductivity, impedance matching, mechanical strength, and durability, while offering design “playbooks’’ for three front - line needs: low - reflectance EMI absorbers, flexible medical aprons, and structural aerospace panels <jats:bold>.</jats:bold> Finally, it looks ahead to the next breakthroughs: corrosion - proof 2D interfaces, scalable filler dispersion, frequency - tuned architectures, and data - guided materials discovery that could make polymer shielding a mainstream multifunctional technology. </jats:p>