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Keywords = icephobic

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8 pages, 949 KB  
Proceeding Paper
Hydrophobic and Icephobic Epoxy Coatings Containing Silane Agents and Functional Additives
by Viviana Nebbioso, Aurelio Bifulco, Claudio Imparato, Liberata Guadagno, Marialuigia Raimondo, Jessica Passaro, Pietro Russo, Giuseppe Vitiello, Giulio Malucelli, Antonio Aronne and Amedeo Amoresano
Eng. Proc. 2026, 133(1), 148; https://doi.org/10.3390/engproc2026133148 - 14 May 2026
Viewed by 394
Abstract
Ice accumulation on aircraft surfaces severely affects aerodynamic performance by increasing drag and reducing lift, leading to stall conditions. Conventional thermal and pneumatic anti-/de-icing systems, although widely used, have some disadvantages, including high cost, inefficiency, and environmental unsustainability. Hydrophobic and icephobic coatings have [...] Read more.
Ice accumulation on aircraft surfaces severely affects aerodynamic performance by increasing drag and reducing lift, leading to stall conditions. Conventional thermal and pneumatic anti-/de-icing systems, although widely used, have some disadvantages, including high cost, inefficiency, and environmental unsustainability. Hydrophobic and icephobic coatings have emerged as a promising alternative to reduce ice adhesion and delay ice formation. This paper reviews the use of silane agents in epoxy-based coatings, incorporating functional additives such as natural fibers, quantum dots, and nanoparticles, to enhance hydrophobicity. Results demonstrated that the combination of silanes and functional additives affects surface features and wettability, improving hydrophobicity. These case studies show the potential of this approach in the development of coatings for advanced aircraft ice-protection applications. Full article
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20 pages, 4862 KB  
Article
Ice-Phobic Keratin–Polymer Impregnation for Concrete Pavements: Performance, Adhesion, and Durability Assessment
by Rauan Lukpanov, Lyailya Kabdyrova, Duman Dyussembinov and Denis Tsigulyov
Infrastructures 2026, 11(4), 113; https://doi.org/10.3390/infrastructures11040113 - 25 Mar 2026
Viewed by 510
Abstract
This study presents the development and experimental evaluation of an impregnation composition for cement concrete pavements aimed at improving ice-phobic performance while preserving tire–pavement adhesion characteristics. The formulation is based on a combination of keratin-containing raw materials and water-soluble polymer components. Optimization showed [...] Read more.
This study presents the development and experimental evaluation of an impregnation composition for cement concrete pavements aimed at improving ice-phobic performance while preserving tire–pavement adhesion characteristics. The formulation is based on a combination of keratin-containing raw materials and water-soluble polymer components. Optimization showed that a polymer concentration of 2.5% reduces concrete water absorption by 49–53% compared with untreated specimens. Freezing tests conducted at temperatures of 0 to −5 °C demonstrated an additional reduction in water absorption of treated specimens by 33–40% relative to uncoated concrete and improved resistance to ice formation. The influence of the impregnation on tire–pavement interaction was assessed using a direct shear method, revealing minor changes in friction coefficients of up to ~6% for polished and less than 1% for rough surfaces, remaining within acceptable safety limits. Wear resistance was evaluated through rolling tests with model vehicle wheels, where laboratory abrasion occurred after several thousand loading cycles, while probabilistic correction accounting for trajectory variability indicated an extension of service life to the order of tens of thousands of vehicle passes. The results confirm the potential of the keratin–polymer impregnation as an effective approach for enhancing the durability and operational safety of concrete pavements in cold climates. Full article
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26 pages, 3189 KB  
Review
Advances and Challenges in Ice Accretion on Passive Icephobic Surfaces
by Milad Hassani and Moussa Tembely
Processes 2026, 14(6), 985; https://doi.org/10.3390/pr14060985 - 19 Mar 2026
Cited by 2 | Viewed by 782
Abstract
Ice accretion on aircraft, wind-turbine blades, power networks, civil infrastructure, and exposed sensors poses severe safety risks and economic costs. Passive icephobic surfaces mitigate icing by delaying heterogeneous nucleation, altering droplet impact/solidification and wetting transitions, and/or weakening the ice–substrate bond so that accreted [...] Read more.
Ice accretion on aircraft, wind-turbine blades, power networks, civil infrastructure, and exposed sensors poses severe safety risks and economic costs. Passive icephobic surfaces mitigate icing by delaying heterogeneous nucleation, altering droplet impact/solidification and wetting transitions, and/or weakening the ice–substrate bond so that accreted ice sheds under modest aerodynamic, gravitational, or vibrational loads. This review synthesizes recent progress using a unified mechanism framework linking (i) nucleation and early freezing, (ii) droplet dynamics during impact or condensation/frosting, and (iii) ice accretion and removal governed by interfacial fracture. Smooth low-surface-energy coatings, textured (superhydrophobic) surfaces, slippery liquid-infused porous surfaces (SLIPS), and low-interfacial-toughness strategies are critically compared in terms of achievable performance ranges, failure modes, durability limits, fabrication scalability, and test-method dependence. Ice-adhesion measurement approaches (push-off, pull-off/tensile, centrifugal) are assessed and a minimum reporting checklist is provided to improve comparability. Case studies across aviation, wind energy, power infrastructure, sensors, and emerging civil-engineering coatings highlight that durability and scale-dependent failure modes remain the dominant barriers to durable, energy-free icing mitigation. The review concludes with priorities for eco-friendly chemistries, self-healing or renewable layers, standardized testing/reporting, and data-driven (machine learning-assisted) optimization to accelerate translation into durable passive ice-mitigation technologies. Full article
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20 pages, 4430 KB  
Article
Anti-Icing Performance of Base Formulations for Coatings for Aeronautical Applications
by Filomena Piscitelli, Andrea Diana, Giovanni Bruno, Gianmarco Caldore, Veronica Ambrogi and Giovanni Filippone
Coatings 2026, 16(3), 298; https://doi.org/10.3390/coatings16030298 - 28 Feb 2026
Viewed by 863
Abstract
Icing on surfaces presents a significant challenge across various technological fields, with added weight and operational interference impacting aircraft wings, wind turbine blades, and electrical equipment. While electrothermal methods effectively accelerate ice melting through the Joule effect, their substantial cost and energy consumption [...] Read more.
Icing on surfaces presents a significant challenge across various technological fields, with added weight and operational interference impacting aircraft wings, wind turbine blades, and electrical equipment. While electrothermal methods effectively accelerate ice melting through the Joule effect, their substantial cost and energy consumption necessitate careful consideration. In the past two decades, anti-icing and icephobic coatings have garnered significant interest due to advancements in nanomaterials and a deeper understanding of ice nucleation and adhesion. These coatings are designed to prevent water droplet adhesion, delay freezing, and/or reduce ice adhesion, without the need for additional energy. Moreover, the combination of active Ice Protection Systems with passive coatings could prevent ice formation with an improved energy efficiency and reduced CO2 emissions. Aligned with this aim, this study focuses on the development of anti-icing coatings, detailing the selection and characterization of the materials used in the coating formulations, including their chemical and physical properties. Subsequently, the experimental results are presented and analyzed, focusing on the characterization and anti-icing performance of the fabricated coatings through a series of tests. Finally, it concludes with a discussion of the key findings, useful for the formulation of advanced anti-icing coatings mainly for aeronautical applications. Full article
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16 pages, 2248 KB  
Article
Synergistic Aging Resistance and Autonomous Self-Healing in Trimethylolpropane Triglycidyl Ether-Based Anti-Icing Coatings
by Siyu Yan, Zhuang Tang, Bichen Pan, Xin Chen, Bohang Zhang and Jiazheng Lu
Coatings 2026, 16(1), 13; https://doi.org/10.3390/coatings16010013 - 21 Dec 2025
Viewed by 661
Abstract
Anti-icing materials have attracted considerable research interest due to their potential applications in preventing ice accretion and growth. However, a major challenge in the field is how to enhance durability while maintaining anti-icing performance. This study proposes a facile fabrication method for anti-icing [...] Read more.
Anti-icing materials have attracted considerable research interest due to their potential applications in preventing ice accretion and growth. However, a major challenge in the field is how to enhance durability while maintaining anti-icing performance. This study proposes a facile fabrication method for anti-icing coatings with anti-aging and self-healing abilities. A three-dimensionally cross-linked block copolymer, synthesized from polydimethylsiloxane, 4-aminophenyl disulfide, and trimethylolpropane triglycidyl ether, yielded a coating with excellent anti-icing/de-icing performance, including a low ice adhesion strength (29.2 kPa) and a high icing delay time (1389 s). The introduction of 4-aminophenyl disulfide enables dynamic disulfide bond reorganization and aromatic framework formation, synergistically conferring the icephobic coating with self-repair mechanisms and an anti-aging function. The coating exhibited a rapid self-healing capability (within 4 h), which is facilitated by the dynamic exchange of its hydrogen and disulfide bonds. Furthermore, the material demonstrated outstanding durability against physical wear and ultraviolet radiation. After being subjected to a 1000-cycle abrasion test and ultraviolet aging, the coating successfully retained more than 70% of its original performance in both icing delay time and ice adhesion strength. This paper proposes a facile strategy for developing self-healing and anti-aging anti-icing coatings and proposes innovative strategies for multifunctional anti-icing coatings. Full article
(This article belongs to the Section Functional Polymer Coatings and Films)
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14 pages, 1661 KB  
Article
On the Hydrophobicity, Superhydrophobicity and Icephobicity of Etched Aluminum Surfaces
by Marcella Balordi, Andrea Cammi, Alessandro Casali, Francesco Pini and Giorgio Santucci de Magistris
Coatings 2025, 15(11), 1328; https://doi.org/10.3390/coatings15111328 - 14 Nov 2025
Cited by 3 | Viewed by 991
Abstract
Several hydrophobic and superhydrophobic aluminum surfaces were prepared with a three-step process that includes chemical etching, a treatment in hot water and a further coating with fluoroalkysiloxane (FAS). By varying the concentration of the etchant, the immersion time in the etchant and the [...] Read more.
Several hydrophobic and superhydrophobic aluminum surfaces were prepared with a three-step process that includes chemical etching, a treatment in hot water and a further coating with fluoroalkysiloxane (FAS). By varying the concentration of the etchant, the immersion time in the etchant and the boiling time, surfaces characterized by different roughness were obtained, with a wettability ranging from hydrophobic to superhydrophobic values. The icephobic properties were tested and the results reveal important differences among the samples, related to the roughness of the surface and the etching and boiling treatment processes. Full article
(This article belongs to the Special Issue Superhydrophobic Surfaces and Coatings)
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18 pages, 4703 KB  
Article
Nanoparticle-Free 3D-Printed Hydrophobic Surfaces for Ice Mitigation Applications
by Ranim Zgaren, Maryam Hosseini, Reza Jafari and Gelareh Momen
Molecules 2025, 30(15), 3185; https://doi.org/10.3390/molecules30153185 - 30 Jul 2025
Cited by 3 | Viewed by 2046
Abstract
Ice accumulation on exposed surfaces presents substantial economic and safety challenges across various industries. To overcome limitations associated with traditional anti-icing methods, such as the use of nanoparticles, this study introduces a novel and facile approach for fabricating superhydrophobic and anti-icing microstructures using [...] Read more.
Ice accumulation on exposed surfaces presents substantial economic and safety challenges across various industries. To overcome limitations associated with traditional anti-icing methods, such as the use of nanoparticles, this study introduces a novel and facile approach for fabricating superhydrophobic and anti-icing microstructures using cost-effective LCD 3D printing technology. The influence of diverse pillar geometries, including square, cylindrical, hexagonal, and truncated conical forms, was analyzed to assess their effects on the hydrophobic and anti-icing/icephobic performance in terms of wettability, ice adhesion strength, and icing delay time. The role of microstructure topography was further investigated through cylindrical patterns with varying geometric parameters to identify optimal designs for enhancing hydrophobic and icephobic characteristics. Furthermore, the effectiveness of surface functionalization using a low surface energy material was evaluated. Our findings demonstrate that the synergistic combination of tailored microscale geometries and surface functionalization significantly enhances anti-icing performance with reliable repeatability, achieving ice adhesion of 13.9 and 17.9 kPa for square and cylindrical pillars, respectively. Critically, this nanoparticle-free 3D printing and low surface energy treatment method offers a scalable and efficient route for producing high-performance hydrophobic/icephobic surfaces, opening promising avenues for applications in sectors where robust anti-icing capabilities are crucial, such as renewable energy and transportation. Full article
(This article belongs to the Special Issue Micro/Nano-Materials for Anti-Icing and/or De-Icing Applications)
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15 pages, 3703 KB  
Article
A Study on the Hydrophobicity and Icephobicity of Modified Cement-Based Composite Coatings for Anti-/De-Icing of Guardrail Concrete
by Jianping Gao, Pan Zhou, Xianlong Shi, Kang Gu, Hongji Chen, Qian Yang and Zhengwu Jiang
Buildings 2025, 15(13), 2263; https://doi.org/10.3390/buildings15132263 - 27 Jun 2025
Viewed by 1052
Abstract
Guardrail concrete in cold regions frequently suffers from corrosion due to icing and solutions, significantly shortening the service life of the guardrail. This paper proposed a cement-based composite coating for concrete protection. The hydrophobic agent was synthesized using nano-silica, tetraethyl orthosilicate and perfluorodecyltrimethoxysilane [...] Read more.
Guardrail concrete in cold regions frequently suffers from corrosion due to icing and solutions, significantly shortening the service life of the guardrail. This paper proposed a cement-based composite coating for concrete protection. The hydrophobic agent was synthesized using nano-silica, tetraethyl orthosilicate and perfluorodecyltrimethoxysilane and used for coating modification as an additive or by impregnation. Also, a commercial hydrophobic agent was used for comparison. The modified coating was characterized by wettability, mechanical properties, chemical stability and icephobicity tests. The results showed that the coating prepared with the synthetic hydrophobic agent presented a higher contact angle than that prepared with the commercial one during the above tests. Moreover, it featured excellent icephobicity by effectively delaying the time of icing on concrete and reducing the icing mass and ice adhesion strength. In addition, the hydrophobic agent used by impregnation was a better choice for concrete surface protection. Chemical composition and morphology analysis of the coating showed that hydrophobicity and icephobicity were mainly attributed to F-containing functional groups and rough structure with low surface energy. This study provided an application potential of modified cement-based composite coating for anti-/de-icing of guardrail concrete. Full article
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12 pages, 2637 KB  
Article
Proposal for a Controlled Humidity Environment Test Bench for the Accurate Characterization of Icephobic Properties
by Louise Burdin, Anne-Catherine Brulez, Radoslaw Mazurczyk, Jean-Louis Leclercq and Stéphane Benayoun
Micromachines 2025, 16(7), 756; https://doi.org/10.3390/mi16070756 - 27 Jun 2025
Viewed by 917
Abstract
The accumulation of ice on equipment exposed to low temperatures raises major efficiency and safety concerns. To overcome this challenge, various strategies have been developed to create icephobic surfaces. Their characterization typically relies on the measurements of icing delay time (IDT) or ice [...] Read more.
The accumulation of ice on equipment exposed to low temperatures raises major efficiency and safety concerns. To overcome this challenge, various strategies have been developed to create icephobic surfaces. Their characterization typically relies on the measurements of icing delay time (IDT) or ice adhesion strength. However, the absence of standardized testing equipment leads to significant variability, as each research group employs different setups and conditions. This lack of standardization complicates the comparison of results and the evaluation of surface performance. Herein, we describe the development of a new reproducible test bench that allows for simultaneous measurement of ice adhesion strength and IDT under controlled humidity conditions. Results reveal that increasing humidity leads to higher adhesion and lower IDT values. This study highlights the critical influence of humidity and suggests that tests should be performed at low humidity levels in order to accurately assess the intrinsic icephobic properties of surfaces. Full article
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14 pages, 2354 KB  
Article
Design of a Superhydrophobic Photothermal Shape-Memory Material Based on Carbon-Nanotubes-Doped Resin for Anti-Icing/De-Icing Applications
by Yingcheng Zhao, Pei Tian, Xinlin Li, Di Gai and Wei Tong
Materials 2025, 18(11), 2540; https://doi.org/10.3390/ma18112540 - 28 May 2025
Cited by 2 | Viewed by 1366
Abstract
Icing on power lines and wings can cause serious economic damage and safety hazards. While superhydrophobic materials show promise for anti-icing applications, their passive anti-icing mechanisms require external energy activation, highlighting the need for the development of active de-icing materials with energy-to-heat conversion [...] Read more.
Icing on power lines and wings can cause serious economic damage and safety hazards. While superhydrophobic materials show promise for anti-icing applications, their passive anti-icing mechanisms require external energy activation, highlighting the need for the development of active de-icing materials with energy-to-heat conversion capabilities. Here, we developed three photothermal superhydrophobic shape-memory polymers with anti-icing performance (PSSPs), with 3%, 5%, and 7% CNT doping ratios, through a two-step process: resin preparation and laser-processing modification. The results showed that all samples presented good superhydrophobic properties. In addition, the tested materials demonstrated good shape-memory performance (recovery rates were close to 100%). They also showed excellent de-icing performance. Owing to the simplicity of the fabrication process, the material is suitable for mass production. The synergistic interplay between superhydrophobicity and photothermal activation endows the material with dual-functional icephobic performance, demonstrating practical applicability in industrial cryogenic environments. Full article
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16 pages, 2796 KB  
Article
Icephobic Properties of Superhydrophobic Coatings Developed for Aeronautical Applications
by Filomena Piscitelli, Matteo Fanciullo, Antonella Sarcinella, Mario Costantini and Mariaenrica Frigione
Coatings 2025, 15(6), 621; https://doi.org/10.3390/coatings15060621 - 22 May 2025
Cited by 4 | Viewed by 2360
Abstract
Ice accumulation poses a significant hazard to aviation safety, particularly in cold weather conditions, as it can compromise aerodynamic performance, increase structural weight, and diminish lift, occasionally resulting in severe stall incidents. At present, such risks are managed through the use of energy-demanding [...] Read more.
Ice accumulation poses a significant hazard to aviation safety, particularly in cold weather conditions, as it can compromise aerodynamic performance, increase structural weight, and diminish lift, occasionally resulting in severe stall incidents. At present, such risks are managed through the use of energy-demanding active ice protection systems (IPSs), which operate either by inhibiting ice formation (anti-icing) or by removing existing ice (de-icing). Nonetheless, in the context of future sustainable aviation, there is a pressing need to develop IPSs with lower energy requirements. A promising approach involves hybrid IPSs that integrate conventional active systems with passive superhydrophobic or icephobic surface treatments, which are capable of preventing, delaying, or minimizing ice buildup. These systems offer the potential to substantially decrease the energy consumption and consequently the CO2 emissions. Furthermore, in accordance with FAA regulations, active IPSs are not permitted to operate during takeoff and initial flight stages to prevent any reduction in engine thrust. These two reasons emphasize the critical importance of developing efficient coatings that, on the one hand, promote the mobility of water droplets, hereby preventing ice formation, as achieved by superhydrophobic surfaces, and on the other hand, facilitate ice detachment, as required for icephobic performance. In this context, the primary objective of the present work is to emphasize the icephobic properties of two superhydrophobic coatings. To achieve this, an extensive characterization is first conducted, including wettability, Surface Free Energy (SFE), and surface roughness, to confirm their superhydrophobic nature. This is followed by an assessment of their icephobic performance, specifically in terms of ice adhesion strength, with comparisons made against a commercial aeronautical coating. The results revealed a significant reduction in both the wettability and SFE of the developed coatings compared to the reference, along with a marked decrease in ice adhesion strength, thereby demonstrating their icephobic properties. Future activities will focus on the combination of coatings with active IPS in order to assess the energy efficiency under extensive icing conditions where both superhydrophobic and icephobic properties are required. Full article
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37 pages, 12224 KB  
Review
Research Progress of Photothermal Superhydrophobic Surfaces for Anti-Icing/Deicing
by Hui Gao, Tianjun Yin, Jieyin Ma, Yuqin Zhou, Ke Li and Jiayi Bao
Molecules 2025, 30(9), 1865; https://doi.org/10.3390/molecules30091865 - 22 Apr 2025
Cited by 27 | Viewed by 6487
Abstract
Photothermal superhydrophobic surfaces with micro/nano-structured morphologies have emerged as promising candidates for anti-icing and deicing applications due to their exceptional water repellency and efficient solar-to-thermal conversion. These surfaces synergistically integrate the passive icephobicity of superhydrophobic coatings with the active heating capability of photothermal [...] Read more.
Photothermal superhydrophobic surfaces with micro/nano-structured morphologies have emerged as promising candidates for anti-icing and deicing applications due to their exceptional water repellency and efficient solar-to-thermal conversion. These surfaces synergistically integrate the passive icephobicity of superhydrophobic coatings with the active heating capability of photothermal materials, offering energy-efficient and environmentally friendly solutions for sectors such as aviation, wind energy, and transportation. Hence, they have received widespread attention in recent years. This review provides a comprehensive overview of recent advances in photothermal superhydrophobic coatings, focusing on their anti-icing/deicing mechanisms, surface wettability, and photothermal conversion performance for anti-icing/deicing applications. Special emphasis is placed on material categories, including metals and their compounds, carbon-based materials, and polymers, analyzing their structural features and application effectiveness. Furthermore, the application of anti-icing/deicing in various fields is described. Finally, perspectives on future development are presented, including pursuing fluorine-free, cost-effective, and multifunctional coatings to meet the growing demand for innovative, sustainable anti-icing/deicing technologies. Full article
(This article belongs to the Special Issue Micro/Nano-Materials for Anti-Icing and/or De-Icing Applications)
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53 pages, 13954 KB  
Review
Progress in Icephobic Coatings for Wind Turbine Protection: Merging Chemical Innovation with Practical Implementation
by Ghazal Minoofar, Amirhossein Jalali Kandeloos, Mohammad Sadegh Koochaki and Gelareh Momen
Crystals 2025, 15(2), 139; https://doi.org/10.3390/cryst15020139 - 27 Jan 2025
Cited by 12 | Viewed by 9416
Abstract
Ice accumulation on wind turbine blades poses a significant challenge to turbine performance and safety, and these issues have led to extensive research on developing effective anti-icing methods. Polymer-based icephobic coatings have emerged as promising solutions, given their passive nature and low energy [...] Read more.
Ice accumulation on wind turbine blades poses a significant challenge to turbine performance and safety, and these issues have led to extensive research on developing effective anti-icing methods. Polymer-based icephobic coatings have emerged as promising solutions, given their passive nature and low energy requirements. However, developing effective icephobic coatings is a complex task. In addition to anti-icing properties, factors such as mechanical strength, durability, and resistance to UV, weathering, and rain erosion must be carefully considered to ensure these coatings withstand the harsh conditions faced by wind turbines. The main challenge in coating engineering is mastering the chemistry behind these coatings, as it determines their performance. This review provides a comprehensive analysis of the suitability of current icephobic coatings for wind turbine applications, emphasizing their alignment with present industrial standards and the underlying coating chemistry. Unlike previous works, which primarily focus on the mechanical aspects of icephobicity, this review highlights the critical yet underexplored role of chemical composition and explores recent advancements in polymer-based icephobic coatings. Additionally, earlier studies largely neglect the specific standards required for industrial applications on wind turbines. By demonstrating that no existing coating fully meets all necessary criteria, this work underscores both the urgency of developing icephobic coatings with improved durability and the pressing need to establish robust, application-specific standards for wind turbines. The review also combines insights from cutting-edge research on icephobic coatings that are coupled with active de-icing methods, known as the hybrid approach. By organizing and summarizing these innovations, the review aims to accelerate the development of reliable and efficient wind energy systems to pave the way for a cleaner and more sustainable future. Full article
(This article belongs to the Special Issue Celebrating the 10th Anniversary of International Crystallography)
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15 pages, 5042 KB  
Article
Efficient Corona Suppression Coatings and Their Behavior in Corrosive and Icy Environments
by Kirill A. Emelyanenko, Maria A. Teplonogova, Alexandre M. Emelyanenko and Ludmila B. Boinovich
Materials 2025, 18(2), 254; https://doi.org/10.3390/ma18020254 - 9 Jan 2025
Cited by 2 | Viewed by 1841
Abstract
High-voltage transmission lines face significant challenges due to environmental exposure, including corona discharge, ice accretion, and corrosion, which impact their durability and operational efficiency. This study investigates the performance of hydrophilic and superhydrophilic organosilane coatings applied to high-voltage wires to address these issues. [...] Read more.
High-voltage transmission lines face significant challenges due to environmental exposure, including corona discharge, ice accretion, and corrosion, which impact their durability and operational efficiency. This study investigates the performance of hydrophilic and superhydrophilic organosilane coatings applied to high-voltage wires to address these issues. Using a combination of experimental setups simulating real-world conditions, we evaluated corona discharge losses, ice adhesion, and corrosion resistance on coated and uncoated wires. The results reveal that hydrophilic and superhydrophilic organosilane coatings offer a substantial reduction in corona discharge power losses, with a 25–60% decrease compared to bare wires. Additionally, the proposed hydrophilic coating exhibits ice adhesion characteristics similar to bare wires, in contrast to the higher ice adhesion observed for superhydrophilic samples. Corrosion tests further highlight the performance of the hydrophilic coating, which reduces corrosion currents by approximately threefold compared to bare wires, demonstrating enhanced protection and long-term stability. While superhydrophilic coatings offer some advantages in corona discharge reduction, their increased ice adhesion and higher corrosion rates limit their applicability. The hydrophilic organosilane coating thus emerges as the optimal tradeoff, balancing effective corona discharge mitigation, moderating ice adhesion, and enhancing corrosion resistance, making it a promising solution for improving the performance and longevity of high-voltage transmission lines. Full article
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11 pages, 2135 KB  
Article
Novel Numerical Method for Studying Water Freezing on Surfaces Texturized by Laser
by Samih Haj Ibrahim, Tomasz Wejrzanowski, Christian W. Karl, Espen Sagvolden, Jakub Karwaszewski, Monika Pilz, Bartłomiej Przybyszewski and Rafał Kozera
Materials 2024, 17(24), 6155; https://doi.org/10.3390/ma17246155 - 17 Dec 2024
Viewed by 1848
Abstract
Within this study, a methodology for the numerical simulation of droplet freezing, including a micrometer texturized pattern, was developed. The finite volume method was then applied to simulate the behavior of water droplets. The procedure was divided into two processes: stabilization and freezing. [...] Read more.
Within this study, a methodology for the numerical simulation of droplet freezing, including a micrometer texturized pattern, was developed. The finite volume method was then applied to simulate the behavior of water droplets. The procedure was divided into two processes: stabilization and freezing. In the stabilization step, the droplet was dropped onto the material surface and took an equilibrium shape. In the second step, additional energy equation and temperature boundary conditions were applied to perform freezing simulation. Based on the laser-texturized samples of polyurethane-coated metal substrates studied with freezing delay experiments, numerical models were generated, and droplet freezing simulations were performed. Three cases were studied—non-texturized and texturized with respectively linear and triangular patterns. The obtained simulation results of freezing time were compared with experimental measurements to evaluate the proposed methodology. The study revealed that despite the inability to predict accurate freezing delay time, the proposed methodology can be used to compare the freezing delay capabilities for different texturized patterns. Additionally, the proposed model renders it possible to analyze additional aspects of wetting and freezing of the droplet on rough surfaces, which may be helpful in understanding these processes. Full article
(This article belongs to the Special Issue Surface Technology and Coatings Materials)
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