Nature Communications (Aug 2023)

Ultra-resilient multi-layer fluorinated diamond like carbon hydrophobic surfaces

  • Muhammad Jahidul Hoque,
  • Longnan Li,
  • Jingcheng Ma,
  • Hyeongyun Cha,
  • Soumyadip Sett,
  • Xiao Yan,
  • Kazi Fazle Rabbi,
  • Jin Yao Ho,
  • Siavash Khodakarami,
  • Jason Suwala,
  • Wentao Yang,
  • Omid Mohammadmoradi,
  • Gozde Ozaydin Ince,
  • Nenad Miljkovic

DOI
https://doi.org/10.1038/s41467-023-40229-6
Journal volume & issue
Vol. 14, no. 1
pp. 1 – 13

Abstract

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Abstract Seventy percent of global electricity is generated by steam-cycle power plants. A hydrophobic condenser surface within these plants could boost overall cycle efficiency by 2%. In 2022, this enhancement equates to an additional electrical power generation of 1000 TWh annually, or 83% of the global solar electricity production. Furthermore, this efficiency increase reduces CO2 emissions by 460 million tons /year with a decreased use of 2 trillion gallons of cooling water per year. However, the main challenge with hydrophobic surfaces is their poor durability. Here, we show that solid microscale-thick fluorinated diamond-like carbon (F-DLC) possesses mechanical and thermal properties that ensure durability in moist, abrasive, and thermally harsh conditions. The F-DLC coating achieves this without relying on atmospheric interactions, infused lubricants, self-healing strategies, or sacrificial surface designs. Through tailored substrate adhesion and multilayer deposition, we develop a pinhole-free F-DLC coating with low surface energy and comparable Young’s modulus to metals. In a three-year steam condensation experiment, the F-DLC coating maintains hydrophobicity, resulting in sustained and improved dropwise condensation on multiple metallic substrates. Our findings provide a promising solution to hydrophobic material fragility and can enhance the sustainability of renewable and non-renewable energy sources.