Porous Polydimethylsiloxane/Au Composites as Solar‐Light Absorbers for Light‐Driven Thermoelectric Applications

Solar thermoelectric (TE) generators may potentially provide a viable alternative to photovoltaic devices for producing electrical energy from renewable sources. In this approach, the conversion of solar radiation into heat is essential to enhance the performance of TE devices, which necessitates the development of efficient solar light absorbers. Metal nanoparticles (NPs) have gained much attention in this regard because they can convert light into heat via plasmon‐mediated photothermal effects. In this study, porous nanocomposites comprising polydimethylsiloxane (PDMS) and Au NPs are prepared. In the PDMS/Au composites, the narrow extinction spectrum of Au NPs is extended over longer wavelengths by plasmonic hybridization to promote the light absorption property of the NPs. In addition, the porous structure induces strong scattering of incident light, which further enhances the absorption efficiency of the Au NPs. Consequently, the plasmon‐mediated photothermal effects of Au NPs are noticeably enhanced and increased the temperature of the PDMS/Au composites to as high as 75.7 °C under artificial solar radiation, compared to 42.1 °C without the Au NPs. By applying the PDMS/Au composites to commercial TE devices, the electrical performance of the TE devices is enhanced by approximately threefold. An efficient solar‐to‐heat conversion is realized by porous polydimethylsiloxane (PDMS)/Au composites, at which the plasmonic heating of Au nanoparticles is strongly enhanced by the light scattering property of porous structures. By applying the PDMS/Au composites on a thermoelectric device as heat source, the performance of thermoelectric device can be enhanced under light illumination.