J. Mater. Sci. Technol. ›› 2020, Vol. 49: 106-116.DOI: 10.1016/j.jmst.2020.02.022
• Research Article • Previous Articles Next Articles
Aeree Kima,*,1(), Seonghyeon Kima,1, Myoung Huha, Hyungmo Kimb, Chan Leeb
Received:
2019-10-21
Revised:
2020-01-30
Accepted:
2020-02-01
Published:
2020-07-15
Online:
2020-07-17
Contact:
Aeree Kim
About author:
1 These authors contributed equally as co-first authors to this work.
Aeree Kim, Seonghyeon Kim, Myoung Huh, Hyungmo Kim, Chan Lee. Superior anti-icing strategy by combined sustainable liquid repellence and electro/photo-responsive thermogenesis of oil/MWNT composite[J]. J. Mater. Sci. Technol., 2020, 49: 106-116.
Fig. 1. Comprehensive anti-icing strategy of SLEC. (a) Passive anti-icing property with (a-1) liquid repellence, and (b) active deicing function of the SLEC. FLIR and optical images when the SLEC is heated by (b-1) Joule heating, and by (b-2) laser illumination.
Fig. 2. Results for sustainable liquid repellence. (a) Test to show maintenance of liquid-repellence after condensation with SLEC (M11L90), SHPo, and SLUG (M0L90). (b) Melting frost slides down M14L90, and (c) subsequent impinging droplets slide off of it. (d) Melting frost remained on SHPo, and (e) subsequent droplets stuck to it. (f) Time lapse images for icing delay time and (g) frost coverage ratio over time on SHPo, M14L90, and M11L90. (h) Frost propagation on M11L90.
Fig. 4. Active anti-icing using electro-thermogenesis. Capability of (a,b) SLUG (M0L90) and SLEC (M14L90) on ice prevention by application of voltage (25 V) on low-temperature Peltier plate (-7 ℃). (c) Water-droplet dripping after test of (a, b). Sample is still on the low-temperature plate. Defrosting capability of (d) SLUG (M0L90) and SLEC (M14L90) on a Peltier plate at 11 ℃, by application of voltage (25 V).
Fig. 5. Active anti-icing function using photo-thermogenesis. (a) Capability of ice prevention of SLUG (M0L60) and SLEC (M14L60) by laser illumination (532 nm, 500 mW/cm2). (b) FLIR images that correspond to (a).
Fig. 6. (a) Syneresis behavior induced by Joule heating for 500 min (b) Temperature increase induced by laser irradiation (532 nm, 500 mW/cm2) for 1 h, and syneresis behavior induced by photothermogenesis. (c) Demonstration of lubricant replenishment. Optical images of SLECs: (left) SLEC in its initial condition after complete removal of remained oil. SLECs after syneresis for 24 h at 70 °C: (middle) sample without replenishment and (right) sample with replenishment. (d) Comparison of weight loss of the two samples.
Fig. 7. (a) Scalable SLEC fabrication (b) self-cleaning property of SLEC. The dirt is removed by the rolling droplet. Stability of liquid repellence after (c) abrasion test, and (d) blade-cutting test. (e) mechanical stability of SLEC under multi-cycles of stretching and bending loading. Here, resistance change ΔR (i.e. the difference resistance after strain to initial resistance R0) was normalized to R0: ΔR?R0. (left. ΔR/R0 of M15L90 as a function of multiple (> 100 times) bending cycles with displacement of 1.2 cm. (right) ΔR/R0 of M15L90 with different off-times TOFF as a function of multiple (> 100 times) stretching and releasing cycles with 35 % strain.
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