Anti-icing properties of femtosecond laser-induced nano and multiscale topographies

Research output: Contribution to journalArticlepeer-review

Authors

Colleges, School and Institutes

External organisations

  • University of Notre Dame

Abstract

Surfaces covered with micro, nano and multiscale topographies are the subject of significant interest due to their ice-repellency properties in the last decade. Ultrafast laser processing is becoming a widely used clean manufacturing technique to fabricate ordered nano and multiscale topographies on metallic surfaces over relatively large areas. In this work, single- tier nano and two-tier multiscale topographies were fabricated on stainless steel surfaces with one-step femtosecond laser processing to impart anti-icing response. Droplet freezing and frost formation on laser treated surfaces were examined at -10 oC and compared with the lubricant- impregnated and superhydrophobic nanoparticle-coated ones. While the hydrophilic nanoscale topography has accelerated the droplet freezing and performed worse than untreated surfaces, their hydrophobic counterparts increased the time to freezing by nearly two times. Overall, the superhydrophobic two-tier multiscale topography has significantly delayed both the droplet freezing time and frost formation on surfaces. Furthermore, the two-tier multiscale topography has sustained its anti-icing response even after being subjected to 25 abrasion cycles, while the surfaces with only nanoscale topography and nanoparticle-coating lost their functionality in only 10 cycles. Therefore, such robust two-tier multiscale topographies devoid of any coatings can enable and underpin many industrial applications where ice accumulation on surfaces results in performance degradation, e.g. in aerospace, refrigeration, air-conditioning and energy applications.

Details

Original languageEnglish
Article number149443
JournalApplied Surface Science
Volume552
Early online date17 Mar 2021
Publication statusPublished - 30 Jun 2021

Keywords

  • Anti-icing, femtosecond laser, LIPSS, superhydrophobic, XPS, frost