Abstract

Anti-icing coatings reduce the freezing onset temperature for water by changing the chemical and physical environment at the water-substrate interface to prevent ice nucleation and growth. Graphene oxide has several attributes that make it attractive as an anti-icing coating and it has been theoretically predicted that graphene oxide has a lower freezing onset temperature than pristine graphene. Here, we test this hypothesis using carefully prepared, well-characterized graphene oxide substrates. We compare the water contact angle for graphene and graphene oxide coatings, both prepared on iridium(111) surfaces. The results show both materials to be transparent to wetting, but indicate a lower freezing onset temperature for graphene oxide than for pristine graphene. The measured water contact angles are dominated by the properties of the underlying Ir(111) substrate while the freezing onset temperature is dictated by the functional groups present on the graphene basal plane. We suggest that the lowering of the freezing onset temperature is caused by the formation of a viscous water layer on the surface. Scanning tunneling microscopy and x-ray photoelectron spectroscopy data are used to evaluate the robustness of the coating material and suggest ways to improve the long-term performance, namely by advancing strategies to avoid water intercalation.

Highlights

  • Oxygen-functionalized graphene is one of the most common graphene derivatives

  • Graphene oxide is non-stoichiometric with a O:C ratio usually in the range 0.3e0.5 depending on the oxidation conditions during the

  • In FCC regions, the neighboring carbon atom lies above an iridium atom in the second surface layer while in HCP the neighboring carbon atom lies above an Ir atom located in the third layer

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Summary

Introduction

Graphene oxide was synthesized for the first time by exposing graphite to strong acids by B. Graphene oxide is usually produced by the Hummers’ method, see e.g. Ref. 2. It can be made into fibers [2], membranes [3], papers [4] and freestanding multilayered films [5], and it can be drop-casted onto various substrates [6]. The basal plane of chemically synthesized graphene oxide is mainly covered with hydroxyl- and epoxy groups, see Fig. 1. The edges likely contain carboxyl-, carbonyl- and phenol groups [12]. Graphene oxide is non-stoichiometric with a O:C ratio usually in the range 0.3e0.5 depending on the oxidation conditions during the

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