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Hierarchically Engineered Titanium Suboxide Films for High-Efficiency Solar Thermal Conversion

Materials Science 2025-10-07 v1

Abstract

We report the development of broadband solar absorber coatings based on titanium suboxide composite thin films on aluminium substrates. The films are fabricated via scalable DC magnetron sputtering using a Ti target, followed by post-annealing in a fixed O2O_2 partial pressure of 0.45 mbar. By tuning deposition time and annealing temperature, a composite phase of Ti2O3Ti_2O_3 and TiO2TiO_2 was achieved. The Raman mapping of the films substantiates the distribution and coexistence of the two phases. The optimized sample, deposited for 10 min and annealed at 500 oC^oC, exhibited a superior solar absorptance (αs{\alpha}_s = 0.913) and optimally low thermal emittance (ϵt{\epsilon}_t = 0.11). Nevertheless, the 15- and 20-min deposited films also showed a promising absorptance (>0.85) and emittance values (<0.13). Morphological studies revealed island-type nanostructures, leading to enhanced photothermal performance via electric field confinement, which is validated by optical simulations. This work provides a promising route toward efficient, scalable, and cost-effective spectrally selective solar absorbers for solar thermal applications.

Keywords

Cite

@article{arxiv.2510.03710,
  title  = {Hierarchically Engineered Titanium Suboxide Films for High-Efficiency Solar Thermal Conversion},
  author = {Silpa S and Ann Eliza Joseph and Srinivas G and Harish C Barshilia and Vinayak B Kamble},
  journal= {arXiv preprint arXiv:2510.03710},
  year   = {2025}
}
R2 v1 2026-07-01T06:16:52.094Z