fig3

Screen printing as a scalable manufacturing approach for thermoelectric devices

Figure 3. Screen-printing-enabled geometric design space for TEDs. Film-based architectures: (A) Wearable CuAgSe thermoelectric arrays fabricated on flexible substrates for body-heat harvesting. Reproduced with permission[20]. Copyright 2025, Wiley; (B) Pattern-defined thermoelectric tracks demonstrating circuit-level integration on diverse substrates. Reproduced under a Creative Commons Attribution 4.0 International License[31]. Copyright 2022, Wiley; (C) High-resolution micro-thermoelectric generators featuring radially defined p-n geometries. Reproduced with permission[85]. Copyright 2019, Elsevier; Bulk-based architectures: (D) Vertically integrated p-n arrays on ceramic substrates enabled by layer-by-layer printing and hybrid microfabrication. Reproduced with permission[37]. Copyright 2017, Royal Society of Chemistry; (E) Semi-flexible multilayer TEDs fabricated on paper-based substrates. Reproduced with permission[66]. Copyright 2023, Wiley; (F) Stacked thermoelectric modules incorporating interfacial layers for contact-resistance reduction. Reproduced under a Creative Commons Attribution 3.0 International License[21]. Copyright 2025, Royal Society of Chemistry. CCNT: Chitin nanocrystals/multiwalled carbon nanotube; PET: polyethylene terephthalate; TE: thermoelectric; UV: ultraviolet.

Soft Science
ISSN 2769-5441 (Online)

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Portico

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