Synthesis of Linear Black Gold Nanostructures Processable as Sunlight and Low‐Energy Light Collecting Films for Photo‐Thermoelectricity

As one of the effort to cope with the energy crisis and carbon neutrality, utilization of low‐grade energy generated indoors (e.g., light) is imperative because this saves building and house energy, which accounts for ≈40% of total energy consumption. Although photovoltaic devices could contribute t...

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Published in:Advanced science 2023-05, Vol.10 (13), p.e2207415-n/a
Main Authors: Kim, Jeong Han, Pyun, Seung Beom, Choi, Min Ju, Yeon, Ji Won, Hwang, Young Ji, Cho, Eun Chul
Format: Article
Language:English
Subjects:
Aqueous solutions
Electricity
Energy
Light
linear black Au nanostructures
low‐energy light collecting films
Nanoparticles
photo‐thermoelectricity
processibility
Sodium
winding and bent
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Summary:As one of the effort to cope with the energy crisis and carbon neutrality, utilization of low‐grade energy generated indoors (e.g., light) is imperative because this saves building and house energy, which accounts for ≈40% of total energy consumption. Although photovoltaic devices could contribute to energy savings, it is also necessary to harvest heat from indoor lights to generate electricity because the light absorbed by materials is mostly transformed into heat. For daily life uses, materials should not only have high absorptance and low emittance but also be easily processed into various forms. To this end, this work synthesizes black aqueous suspensions containing winding and bent linear gold nanostructures with diameters of 3–5 nm and length‐to‐diameter ratios of ≈4–10. Their optical and photo‐thermal characteristics are understood through experimental and theoretical investigations. Black gold nanostructures are conveniently processed into metal‐dielectric films on metal, glass, and flexible substrates. The film on copper has an absorptance of 0.97 and an emittance of 0.08. Under simulated sunlight and indoor LED light illumination, the film has equivalent photo‐thermal and photo‐thermoelectric performances to a top‐tier sunlight‐collecting film. This work attempts to modify the film structure to generate more usable electricity from low‐energy indoor light. Black aqueous suspensions containing winding and bent linear gold nanostructures are synthesized to prepare various light collecting films (with high absorptance and low emittance) for the production of photo‐thermoelectricty under the sunlight and low‐energy‐light illumination. Particularly, utilization of heats produced from low‐energy lights could save building energy, hence deal with the energy crisis and carbon neutrality.
ISSN:2198-3844
2198-3844
DOI:10.1002/advs.202207415