Scalable and durable polymeric icephobic and hydrate-phobic coatings

Sojoudi, Hossein; Arabnejad, H.; Raiyan, Asif; Shirazi, Siamack A.; McKinley, Gareth H.; Gleason, Karen K.

doi:10.1039/c8sm00225h

Cited by 48 publications

(32 citation statements)

References 57 publications

(91 reference statements)

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“…As described in several studies [12,39,49,50], the ice-phobic behavior of the SHP surface can be attributed to the high water repellency and to the existence of an "air-cushion" on the surface of the sample that maintain it partially unwetted during the ice formation or that considerably reduce the contact area of ice on the surface. The ice-phobic results obtained for SHP are comparable or better than those of superhydrophobic materials reported in the literature [51][52][53].…”

Section: Ice-phobic Propertiessupporting

confidence: 77%

A Novel Simple Anti-Ice Aluminum Coating: Synthesis and In-Lab Comparison with a Superhydrophobic Hierarchical Surface

2020

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A simple process to obtain a slippery surface with anti-ice and ice-phobic properties has been developed and characterized in laboratory. The coating is realized by growing a nanostructured pseudo-boehmite on an aluminum substrate and applying an environmentally compatible final functionalization consisting of a fluorine-free oligomeric short-chain alkylfunctional silane. The resulting surface is conceptually similar to a slippery liquid infused porous surface (SLIP) material, but the porous infrastructure is inorganic and the process to generate it is very simple, rapid and economic. The coating performance in terms of hydrophobicity at room and low temperatures, ice nucleation temperature and ice adhesion forces were assessed in laboratory. Moreover, hydrophobicity persistence was tested after prolonged immersion in acid, basic and saline solutions while the durability of ice-phobic behavior was assessed by repeated shear stress tests. Results are compared with those of a superhydrophobic hierarchical aluminum surface obtained with a fluorinated siloxane. The novel coating shows very good anti-ice properties and relevant durability, with some differences from the fluorinated surface. The novel slippery coating process is promising for industrial applications, also taking into account its environmental compatibility, simplicity and low cost.

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Section: Ice-phobic Propertiessupporting

confidence: 77%

A Novel Simple Anti-Ice Aluminum Coating: Synthesis and In-Lab Comparison with a Superhydrophobic Hierarchical Surface

2020

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“…Surface‐treated polymers have found widespread use in microfluidics, textiles, biomedical applications, electronics, water‐treatment, and energy industries . These surface treatments can be achieved via wide range of processes, the most common routes are to modulate the surface energy of the material to increase or decrease its adhesive, wetting, absorbing, or releasing properties where the polymer is subjected to chemical, ionic, or light‐based treatment processes which can recondition the surface energies by addition of functional groups to the material . Another alternative is to tailor the surface roughness of the polymer by mechanical or chemical abrasion processes where the top layer of the polymers is modified by treatment with wet or dry abrasives.…”

Section: Introductionmentioning

confidence: 99%

Surface Modification of Polymers: Methods and Applications

Nemani

Annavarapu

Mohammadian

et al. 2018

Adv Materials Inter

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225

140

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Low cost, controlled crystallinity, chemical, and mechanical stability enable application of polymers in energy, water, electronics, and biomedical industries. Recent studies have shown that tailoring surface properties of polymers impacts their durability and functionality in these applications. However, the functionality and performance of polymer‐based devices and systems are greatly affected by the modification method and the process parameters, highlighting the need for understanding these methods and their mechanisms of operation in detail. The selection of the modification method invariably decides the properties enhanced in the polymer. In this review, various polymer surface modification treatments are discussed. These methods are categorized into physical, chemical, thermal, and optical ways, while illustrating their advantages and disadvantages. This review also explores the surface modification of polymers by patterning which encompasses one or more surface treatment methods. An application‐oriented study is presented discussing the relative importance of a method pertaining to a specific field of end‐application.

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“…Atmospheric icing is referred to various processes in which water droplets in atmosphere freeze and adhere to surfaces potentially posing severe risks to the security of man-made structures [1,2]. For example, ice and wet snow accumulation on structures such as power transmission lines, bridge cables, wind turbine blades, and aircraft wings can reduce efficiency, cause detrimental environmental consequences, enhance safety hazards, and increase operational costs [3][4][5][6][7]. e cost of damages of wet snow accretion could be in the order of 100 million US dollars per storm [8].…”

Section: Introductionmentioning

confidence: 99%

“…In addition, due to rise in temperature and external forces such as wind and gravity the blocks of accumulated wet snow may fall from structures such as bridge cables and can cause detrimental safety and operational concerns. Recently, development of coatings to prevent ice/snow accumulation and, in case of any formation, reduce their adhesion strength to surfaces has received considerable attention [3,4,10,15]. However, these coatings are far away from being applied to industrial surfaces due to their durability, scalability, and mechanical-robustness issues [10].…”

Section: Introductionmentioning

confidence: 99%

Experimental and Theoretical Studies of Wet Snow Accumulation on Inclined Cylindrical Surfaces

Mohammadian

Sarayloo

Abdelaal

et al. 2020

Modelling and Simulation in Engineering

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Wet snow accumulation on bridge cables and its shedding due to external phenomena such as rise in temperature, wind, and gravity is a serious threat to the safety of cars and pedestrians crossing the bridge. Commonly the accumulated snow on bridge cables is removed by external means such as mechanical removal or heat treatment which are expensive, time-consuming, and high-risk processes and are conducted based on little or no information available regarding the actual size and shape of the accumulated snow. In addition, cleaning of cables using the mechanical methods can potentially lead to erosion of cable materials when applied over years, resulting in enhanced surface roughness and potentially increased wet snow/ice accumulation during future precipitation events, and sometimes might require replacement of cable stays, which is an extremely costly and complicated task. Optimizing the number of mechanical cleaning procedures such as chain release through predicting the shape and thickness of the accumulated snow on the cable stays reduces the cost, time, and risk associated with the process. In this study, wet snow accumulation on torsionally rigid inclined cylinders of high-density polyethylene (HDPE) has been studied experimentally and numerically. A 2-D numerical model has been developed utilizing weather data to predict the thickness and the shape of the accumulated wet snow on inclined cylindrical surfaces. Outdoor experiments were also conducted to measure the density and thickness of accumulated snow, while monitoring the weather data real time. Overall, snow density was found to be linearly increasing with an increase in wind velocity, during snow precipitation. The maximum thickness and shape of the accumulated snow on cables obtained from the numerical model were found to be in good agreement with the outdoor experimental data. This work aims to provide a mean for prediction of snow accumulation on surfaces for optimizing the efficiency of the costly and high-risk snow removal procedures.

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Scalable and durable polymeric icephobic and hydrate-phobic coatings

Cited by 48 publications

References 57 publications

A Novel Simple Anti-Ice Aluminum Coating: Synthesis and In-Lab Comparison with a Superhydrophobic Hierarchical Surface

A Novel Simple Anti-Ice Aluminum Coating: Synthesis and In-Lab Comparison with a Superhydrophobic Hierarchical Surface

Surface Modification of Polymers: Methods and Applications

Experimental and Theoretical Studies of Wet Snow Accumulation on Inclined Cylindrical Surfaces

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