Coatings

11 pages, 2286 KB

Open AccessArticle

Improved Adhesion Strength of Silica Thin Films on Polycarbonate Substrates Without an Interlayer Using Remote Atmospheric-Pressure Chemical Vapor Deposition

by Hayate Endo, Akira Shirakura and Testuya Suzukia

Coatings 2026, 16(5), 593; https://doi.org/10.3390/coatings16050593 (registering DOI) - 13 May 2026

Abstract

Silica thin-film coatings used for surface protection of automotive parts are generally deposited by chemical vapor deposition (CVD). In this study, we investigated substrate pretreatment methods to improve the adhesion between a polycarbonate substrate and a silica thin film during the direct synthesis [...] Read more.

Silica thin-film coatings used for surface protection of automotive parts are generally deposited by chemical vapor deposition (CVD). In this study, we investigated substrate pretreatment methods to improve the adhesion between a polycarbonate substrate and a silica thin film during the direct synthesis of a hard silica thin film on a polycarbonate substrate using remote atmospheric-pressure plasma CVD, without the use of an acrylic primer intermediate layer. Two types of substrate surface treatments were used: flame treatment and silicone baking. With flame treatment, the adhesion strength of the thin film was 43.5 mN, representing a 26% improvement compared to the untreated sample. With the silicone baking treatment, the adhesion strength was 42.3 mN, representing an improvement of approximately 22% compared to the untreated sample. Therefore, it is considered that the adhesion between the polycarbonate substrate and the silica thin film can be improved by controlling the state of the substrate surface through pretreatment. Full article

(This article belongs to the Special Issue Deposition-Based Coating Solutions for Enhanced Surface Properties)

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6 pages, 714 KB

Open AccessEditorial

Advances in Pavement Materials and Civil Engineering

by Jiujiang Wu and Wenjie Jiang

Coatings 2026, 16(5), 592; https://doi.org/10.3390/coatings16050592 (registering DOI) - 13 May 2026

Abstract

Pavement materials and civil engineering constitute the backbone of modern infrastructure systems, directly supporting economic development, urbanization, and societal resilience [...] Full article

(This article belongs to the Special Issue Advances in Pavement Materials and Civil Engineering)

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23 pages, 36307 KB

Open AccessArticle

The Effect of Different Laser Processing Parameters on the Microstructure and Properties of Copper Conductor Joints

by Ming Hu, Wenqian Yu, Qiong Wu, Xinyu Li, Yu Liu, Hongliang Zhang, Lihong Su and Boyong Su

Coatings 2026, 16(5), 591; https://doi.org/10.3390/coatings16050591 (registering DOI) - 12 May 2026

Abstract

To mitigate welding defects in copper wire conductors induced by their high laser reflectivity and thermal conductivity during laser welding, this study combines numerical simulation and experimental testing to investigate the influences of laser processing parameters on the mechanical properties, molten pool dynamic [...] Read more.

To mitigate welding defects in copper wire conductors induced by their high laser reflectivity and thermal conductivity during laser welding, this study combines numerical simulation and experimental testing to investigate the influences of laser processing parameters on the mechanical properties, molten pool dynamic evolution, and microstructural characteristics of copper self-fusion welds and pure Ni powder-filled welds. The results demonstrate that, for self-fusion welding, a moderate increase in laser power and welding time elevates the heat input, which promotes weld penetration and forming quality. The optimal parameter combination (3900 W, 1.0 s) yields a balanced internal densification and grain refinement, with the joint tensile strength reaching a peak of 245 MPa. For Ni powder-filled welding, the infinite solid solubility between Cu and Ni improves interfacial metallurgical bonding. Under the optimal parameters (3500 W, 1.2 s), the joint tensile strength increases to 282 MPa. Heat input exerts a significant effect on the temperature field evolution in both welding processes, yet the molten pool expansion behaviors differ: self-fusion welding exhibits continuous expansion with rising heat input, whereas Ni powder-filled welding displays complex nonlinear variations. Full article

(This article belongs to the Special Issue Laser Welding and Cladding: Recent Developments)

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21 pages, 3336 KB

Open AccessArticle

Prediction of Asphalt Pavement Service Performance Based on a PSO-LSTM Model

by Hong Zhang, Yuanshuai Dong, Yun Hou, Jun Liu, Zhenyu Qian, Xiangjun Cheng and Keming Di

Coatings 2026, 16(5), 590; https://doi.org/10.3390/coatings16050590 (registering DOI) - 12 May 2026

Abstract

Under the constraints of limited maintenance budgets, research on pavement performance prediction is of considerable practical significance for improving the efficiency of maintenance decision-making, optimizing fund allocation, and ensuring highway serviceability. This study was conducted in conjunction with pavement maintenance projects on ordinary [...] Read more.

Under the constraints of limited maintenance budgets, research on pavement performance prediction is of considerable practical significance for improving the efficiency of maintenance decision-making, optimizing fund allocation, and ensuring highway serviceability. This study was conducted in conjunction with pavement maintenance projects on ordinary national and provincial highways in Shanxi Province, China. Representative routes were selected based on the natural zoning and road network scale of Linfen City. A comprehensive factor system influencing pavement service performance was established, encompassing pavement characteristics, traffic attributes, climatic and environmental conditions, and maintenance management levels. By employing Particle Swarm Optimization (PSO) to tune the hyperparameters of a Long Short-Term Memory (LSTM) network, a PSO-LSTM prediction model incorporating a sliding window mechanism was constructed for the Pavement Condition Index (PCI) and Ride Quality Index (RQI). The model achieves coefficients of determination (R²) of 0.845 and 0.869 for PCI and RQI, respectively, enabling dynamic prediction of pavement service performance and thereby providing scientific support and a data-driven basis for the formulation of pavement maintenance strategies. Full article

(This article belongs to the Special Issue Pavement Surface Status Evaluation and Smart Perception)

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29 pages, 6739 KB

Open AccessArticle

Prediction of Casting Defects and Process Parameter Optimization Based on PSO-BP Neural Network with Application to Titanium Alloy Investment Casting

by Dongcheng He, Yingjie Dong and Qi Zhang

Coatings 2026, 16(5), 589; https://doi.org/10.3390/coatings16050589 (registering DOI) - 12 May 2026

Abstract

Process parameter control is critical for reducing casting defects in ZTA2 alloy pump body investment casting. However, there exists a complex nonlinear relationship between parameters such as pouring temperature, pouring time, and shell preheating temperature, and defects including total defect volume, shrinkage porosity, [...] Read more.

Process parameter control is critical for reducing casting defects in ZTA2 alloy pump body investment casting. However, there exists a complex nonlinear relationship between parameters such as pouring temperature, pouring time, and shell preheating temperature, and defects including total defect volume, shrinkage porosity, and shrinkage cavities, posing significant challenges to accurate prediction and optimization. To address this issue, this study proposes an integrated strategy for defect prediction and process optimization that combines the Non-dominated Sorting Genetic Algorithm II (NSGA-II), Particle Swarm Optimization (PSO), and Backpropagation Neural Network (BP neural network). First, an L₂₅(5³) orthogonal experiment was designed, and a dataset consisting of 25 orthogonal samples and 97 random samples was constructed by combining ProCAST simulations, covering the entire parameter domain of pouring temperature, pouring time, and shell preheating temperature. Subsequently, the PSO algorithm was used to optimize the initial weights and thresholds of the BP neural network, and Bayesian regularization and 5-fold cross-validation were introduced to build a high-precision defect prediction model. The SHapley Additive exPlanations (SHAP) analysis was employed to clarify parameter sensitivity and interaction mechanisms, and the NSGA-II was combined to realize multi-objective process optimization. The results show that: compared with the traditional BP neural network, the optimized PSO-BP model improves the coefficient of determination (R²) of the test set for total defect volume prediction by 20.82% and reduces the root mean square error (RMSE) by 33.34%; for shrinkage porosity volume prediction, the R² is increased by 7.93% and the RMSE is reduced by 22.71%, which effectively solves the problems of local optimization and weak generalization ability. Pouring time is the most sensitive parameter affecting defects, and the coupling effect between pouring temperature and pouring time is the strongest. Considering actual production conditions, the superior process parameters are determined as follows: pouring temperature of 1800 °C, pouring time of 4 s, and shell preheating temperature of 475 °C. Compared with the pre-optimization results, this parameter combination reduces the total defect volume by 38.92% and the shrinkage porosity volume by 51.62%. The intelligent optimization framework constructed in this study provides reliable technical support for the accurate control of defects in ZTA2 titanium alloy pump body investment casting, and has important engineering value for improving the quality of castings in industrial production and reducing costs. Full article

(This article belongs to the Section Surface Characterization, Deposition and Modification)

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16 pages, 18891 KB

Open AccessArticle

Mechanical Properties and High Temperature Tribological Behavior of HfTaC Coating for Carbon/Carbon Composites

by Nan Wang, Jing Zhou, Zhaoxin Li, Jiumei Gao, Feilong Jia, Yan Qi, Xu Chen, Hao Lin, Hongliang Liu and Shusheng Xu

Coatings 2026, 16(5), 588; https://doi.org/10.3390/coatings16050588 (registering DOI) - 12 May 2026

Abstract

HfC, TaC, and HfTaC composite coatings were successfully fabricated on SiC-coated carbon/carbon (C/C) composites using the double glow plasma alloying (DGPA) technique. The microstructure, mechanical properties, and tribological behaviors of the coatings were systematically investigated. The HfTaC coating exhibited a dense and uniform [...] Read more.

HfC, TaC, and HfTaC composite coatings were successfully fabricated on SiC-coated carbon/carbon (C/C) composites using the double glow plasma alloying (DGPA) technique. The microstructure, mechanical properties, and tribological behaviors of the coatings were systematically investigated. The HfTaC coating exhibited a dense and uniform structure with good interfacial integrity and a compositionally graded transition layer, effectively relieving thermal stress. The hardness of HfTaC and HfC coatings (approximately 12 GPa) was higher than that of the TaC coating. Moreover, the higher K value (1.02) and H/E ratio (H/E = 0.09, H³/E² = 0.085 GPa) indicate that the HfTaC coating exhibits good load-bearing capacity and toughness. Under both 5 N and 15 N loads in the reciprocating friction, the HfTaC coating maintained the lowest and most stable friction coefficient (~0.18). Under the 15 N load, it exhibited the smallest specific wear rate. Observation of the wear scars revealed that the HfC and TaC coatings suffered from pore formation and flake-like spallation, while the HfTaC coating retained structural integrity with only minor cracks. In high-temperature ball-on-disc friction tests up to 500 °C, the wear mechanism of the HfTaC coating gradually transitioned from mild abrasive wear to severe oxidative and adhesive wear, yet the HfTaC coating still provided effective protection. These findings demonstrate that the DGPA-fabricated HfTaC coating is a promising candidate for enhancing the wear resistance and service durability of C/C composites. Full article

(This article belongs to the Special Issue Tribology of Advanced Films and Coatings: Mechanisms, Properties, and Applications)

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29 pages, 1246 KB

Open AccessReview

Surface-Driven Outgassing Mechanisms in Anodized Aluminum Under Non-Vacuum Conditions: Material Considerations and Mitigation Strategies

by Aravindh Sadhanandham and Rajendran Prabakaran

Coatings 2026, 16(5), 587; https://doi.org/10.3390/coatings16050587 (registering DOI) - 12 May 2026

Abstract

As anodized aluminum components are increasingly deployed in high-power optical and precision industrial systems operating in non-vacuum environments, their outgassing behavior has emerged as a critical material reliability concern. In contamination-sensitive optical assemblies, released volatiles can accumulate on nearby surfaces, leading to haze [...] Read more.

As anodized aluminum components are increasingly deployed in high-power optical and precision industrial systems operating in non-vacuum environments, their outgassing behavior has emerged as a critical material reliability concern. In contamination-sensitive optical assemblies, released volatiles can accumulate on nearby surfaces, leading to haze formation, scattering, and progressive optical degradation. The porous anodic oxide layer retains water, hydrogen, dyes, and processing residues that are released under thermal, photonic, and environmental stresses typical of industrial operation. While most qualification data remain vacuum-centric, equivalent evaluation frameworks for ambient environments are limited. This review analyzes surface-driven desorption mechanisms relevant to non-vacuum systems and provides practical guidance for material and process engineers by evaluating mitigation strategies across the anodizing process chain, including fine-grain substrate selection, controlled anodizing with nickel acetate sealing, post-bake stabilization, and alternative dense coatings such as electroless nickel, sol–gel films, and Acktar. The analysis underscores the need for non-vacuum-specific qualification standards to support reliable material selection and long-term system performance. Full article

(This article belongs to the Section Surface Characterization, Deposition and Modification)

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19 pages, 3355 KB

Open AccessArticle

Modification and Characterization of 6061 Aluminum Alloy Surface with High Thermal Radiation and Self-Cleaning Performance

by Ke Wen, Zhiwei Hao, Guozheng Li and Xian Zeng

Coatings 2026, 16(5), 586; https://doi.org/10.3390/coatings16050586 (registering DOI) - 12 May 2026

Abstract

To meet the requirements for passive heat dissipation and self-cleaning of aluminum alloy enclosures used in 5G base-station active antenna units (AAUs), a scalable surface modification strategy involving sandblasting, NaOH etching, and PFTEOS grafting was developed for 6061 aluminum alloy. Microscale rough structures [...] Read more.

To meet the requirements for passive heat dissipation and self-cleaning of aluminum alloy enclosures used in 5G base-station active antenna units (AAUs), a scalable surface modification strategy involving sandblasting, NaOH etching, and PFTEOS grafting was developed for 6061 aluminum alloy. Microscale rough structures were first constructed by sandblasting, and hierarchical micro/nano structures composed of microscale pits and nanoscale plate-like/coral-like features were subsequently formed through NaOH etching and boiling-water treatment. Finally, a low-surface-energy PFTEOS layer was grafted onto the structured surface to achieve superhydrophobicity. The effects of sandblasting pressure and etching time on surface morphology, chemical composition, wettability, and infrared emissivity were systematically investigated. The results show that sandblasting enhanced infrared emissivity by increasing surface roughness and promoting optical trapping, while NaOH etching further improved emissivity through the formation of hierarchical micro/nano structures and infrared-active AlOOH/Al₂O₃ phases. After PFTEOS grafting, the surface wettability changed from hydrophilic to superhydrophobic, while the high infrared emissivity was maintained. Compared with the untreated aluminum alloy, the modified surface exhibited a remarkable increase in water contact angle from 80.10° to 153.63° and infrared emissivity from 0.0102 to 0.8951. Moreover, the water contact angle remained above 150° after continuous water-jet impact, indicating good preliminary resistance to hydraulic shear. This work provides a feasible surface-engineering route for integrating high infrared emissivity and self-cleaning capability on aluminum alloy surfaces for outdoor thermal management applications. Full article

(This article belongs to the Section Metal Surface Process)

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20 pages, 3005 KB

Open AccessArticle

Synergistic Effect of Temperature and Magnetic Field Orientation on Ni Electrocatalyst Activity and Morphology for Hydrogen Evolution Reaction

by Safya Elsharkawy, Mahmoud M. Youssif and Piotr Żabiński

Coatings 2026, 16(5), 585; https://doi.org/10.3390/coatings16050585 (registering DOI) - 12 May 2026

Abstract

Hydrogen represents a promising clean and renewable energy source. Therefore, improving the efficiency of electrocatalysts is essential for effective hydrogen production. In this work, Ni electrocatalysts were synthesized via the electrodeposition method from ethaline deep eutectic solvent (DES) at 45 °C, 55 °C, [...] Read more.

Hydrogen represents a promising clean and renewable energy source. Therefore, improving the efficiency of electrocatalysts is essential for effective hydrogen production. In this work, Ni electrocatalysts were synthesized via the electrodeposition method from ethaline deep eutectic solvent (DES) at 45 °C, 55 °C, and 65 °C under perpendicular (B_⊥) and parallel (B_‖) magnetic field directions relative to the electrode surface. Scanning electron microscopy (SEM) was employed to investigate the morphological study, which shows that Ni deposits under B_⊥ promote columnar grain growth, while B_‖ favors lateral, compact structures. Furthermore, moderate temperature (55 °C) in the case of using B_⊥ produced finer grains and smoother surfaces compared to other temperatures in the same direction, enhancing the catalytic performance for HER. Electrochemical techniques, including linear sweep voltammetry (LSV) and chronoamperometry, were employed to evaluate the catalytic performance for HER in 1 M NaOH and the adsorption–desorption process, respectively. The results suggest that efficient HER performance is associated with balanced hydrogen adsorption and desorption behavior. The Ni deposit at 55 °C under (B_⊥) exhibited the lowest overpotential (−215 mV) compared to the deposits at 45 °C and 65 °C under the same magnetic field direction, indicating superior overall HER performance. This performance is attributed to balanced hydrogen adsorption–desorption behavior despite the relatively high Tafel slope value (298 mV·dec⁻¹). However, the lowest Tafel slope among the whole samples prepared under both (B_⊥) and (B_‖) was found to be (219 mV·dec⁻¹), reflecting faster kinetics, which was obtained for the sample deposited at 45 °C under (B_‖). Full article

(This article belongs to the Special Issue Advanced Catalytic Coatings and Films for High-Performance Applications)

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30 pages, 10059 KB

Open AccessArticle

Tailoring Mechanical and Surface Properties of Epoxy Coatings with Synthesized Pigment Particles: Microhardness, Adhesion, and Wettability Studies

by Nikola Nedeljković, Ivana O. Mladenović, Marija M. Vuksanović, Jelena Lamovec, Milica Ž. Mušicki Bogdanović, Dana G. Vasiljević-Radović and Radmila Jančić Heinemann

Coatings 2026, 16(5), 584; https://doi.org/10.3390/coatings16050584 (registering DOI) - 12 May 2026

Abstract

Epoxy resins are widely used in coatings and adhesives due to their strong adhesion and processability. In this study, epoxy-based coatings were prepared with two synthesized pigments: cobalt blue and chrome orange. The coatings were applied to aluminum, phosphor bronze, and brass substrates [...] Read more.

Epoxy resins are widely used in coatings and adhesives due to their strong adhesion and processability. In this study, epoxy-based coatings were prepared with two synthesized pigments: cobalt blue and chrome orange. The coatings were applied to aluminum, phosphor bronze, and brass substrates to evaluate mechanical and adhesive performance. Microhardness was analyzed using the Chen–Gao model to exclude substrate effects, while adhesion was assessed via parameter b. Pigment morphology strongly influenced the properties: Pb-orange exhibited hollow micro-tube structures, while Co-blue showed an irregular morphology. Results revealed that epoxy coatings on brass with Pb-orange pigment reached a hardness of 242.6 MPa, compared to 187.2 MPa for Co-blue, representing a 22.8% increase. Adhesion was superior in epoxy/Pb-orange, with values 1.3 times higher than epoxy/Co-blue and 1.8 times higher than neat epoxy on brass. However, pigments have no influence on the intrinsic hardness of the epoxy coating. The orange pigment in the epoxy impairs wetting resistance, while the blue pigmented epoxy coating becomes hydrophobic. In this way, in addition to colorizing epoxy coatings, multifunctional coatings with adjustable adhesion, free surface energy, and hardness are also obtained. These findings highlight the potential of pigment-modified coatings for tailored industrial applications, offering improved properties depending on pigment selection. Full article

(This article belongs to the Section Functional Polymer Coatings and Films)

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18 pages, 9363 KB

Open AccessArticle

Multifunctional Janus Coatings for Synergistic Photothermal and Radiative Regulation in Adaptive Textiles

by Qingman Liu, Hanqi Li, Hao Wang, Ziyi Zang, Wanqi Cui, Yongli Yu, Li Li, Xiaohu Wu and Xiansheng Zhang

Coatings 2026, 16(5), 583; https://doi.org/10.3390/coatings16050583 (registering DOI) - 11 May 2026

Abstract

The escalating energy crisis and global warming drive the demand for all-season self-regulating functional textiles. This study presents a Janus smart textile that combines phase change energy storage with active and passive heating modes, electromagnetic interference shielding, and self-cleaning capabilities. The front surface [...] Read more.

The escalating energy crisis and global warming drive the demand for all-season self-regulating functional textiles. This study presents a Janus smart textile that combines phase change energy storage with active and passive heating modes, electromagnetic interference shielding, and self-cleaning capabilities. The front surface incorporates phase change temperature regulation and thermochromic properties, while the back surface is spray-coated with a transition metal carbide to establish a continuous conductive network. In the low-temperature state, the black surface enhances solar absorption for efficient heating; as the temperature rises, the surface turns white to increase solar reflection and suppress overheating. This mechanism, combined with phase change energy storage, enables the textile to mitigate environmental temperature fluctuations. The MXene layer on the back provides efficient Joule heating and cycling stability under driving voltages of 3 to 5 volts, along with electromagnetic interference shielding dominated by absorption loss. The front hybrid coating further imparts hydrophobic self-cleaning performance. This study offers a strategy for synergistic active and passive thermal management, demonstrating application potential in intelligent outdoor gear and specialized protective outer layers. Full article

(This article belongs to the Special Issue Radiative Cooling and Photothermal Coatings for Sustainable Energy Applications)

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24 pages, 8791 KB

Open AccessArticle

Molecular Dynamic Simulations of Sintering Titanium Nanoparticles in a Novel 3D Printing Process

by Kai Ren, Xiaofei Gao, Rui Yang, Han Hu, Yi Liu and Jianping Fu

Coatings 2026, 16(5), 582; https://doi.org/10.3390/coatings16050582 (registering DOI) - 11 May 2026

Abstract

Titanium (Ti) and its nanoparticles are widely used in 3D printing due to a high corrosion resistance, biocompatibility, and lightweight potential. However, the atomic-scale mechanism of sintering densification and phase transition remains unclear, which limits the performance regulation of additively manufactured Ti components. [...] Read more.

Titanium (Ti) and its nanoparticles are widely used in 3D printing due to a high corrosion resistance, biocompatibility, and lightweight potential. However, the atomic-scale mechanism of sintering densification and phase transition remains unclear, which limits the performance regulation of additively manufactured Ti components. In this work, molecular dynamics simulations were performed to study the sintering and phase-transition behavior of multi-sized Ti nanoparticles under 3D printing conditions. The melting point of 2 nm Ti nanoparticles decreases to about 1000 K, while that of 12 nm particles approaches the bulk value of 1941 K. Two distinct stages were observed during surface-energy-induced phase transition: initial lattice reconstruction at 800–1100 K, followed by complete melting above 1500 K. Smaller nanoparticles exhibited stronger pre-melting and faster atomic diffusion, which effectively filled interparticle pores and reduced the porosity. Increasing particle contact points shortens atomic diffusion paths, accelerates densification, and alleviates stress concentration. This study reveals the size-dependent sintering mechanism of Ti nanoparticles at the atomic level, providing theoretical guidance for the process optimization, microstructure control, and performance improvement of aerospace and biomedical titanium components fabricated by additive manufacturing. Full article

(This article belongs to the Special Issue Recent Progress in Metal Additive Manufacturing and Post-Processing Techniques)

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22 pages, 5243 KB

Open AccessArticle

Optimization of Process Parameters for Single-Pass High-Speed Laser Cladding of Fe-Cr-Ni-B Alloys and Study of Friction Property

by Weiyuan Guo, Anjun Li, Yanyan Wang, Jiaze Huang and Zhiwen Xue

Coatings 2026, 16(5), 581; https://doi.org/10.3390/coatings16050581 (registering DOI) - 11 May 2026

Abstract

High-speed laser cladding shows significant potential for application in the field of high-performance surface hardening due to its low heat input and high cladding efficiency. However, the pool solidification time is significantly reduced at high scanning speeds, resulting in a narrower process window [...] Read more.

High-speed laser cladding shows significant potential for application in the field of high-performance surface hardening due to its low heat input and high cladding efficiency. However, the pool solidification time is significantly reduced at high scanning speeds, resulting in a narrower process window and making it more difficult to ensure coating formation stability and control performance. Therefore, this study employed high-speed laser cladding technology to prepare FeCrNiB alloy coatings, and systematically conducted research on process parameter optimization and friction properties. Firstly, the response surface method (RSM) was used to establish quantitative relationship models between laser power, scanning speed, and powder feed rate and the dilution ratio, forming coefficient, and microhardness. Then, the hybrid differential evolution and NSGA-II algorithm (DE-NSGA-II) was employed for multi-objective optimization. Finally, a systematic analysis was conducted on the friction and wear properties of the coatings produced under the optimal process parameters. The results indicate that the interaction between laser power and scanning speed has a significant impact on the dilution behavior of the coating, while the coupling between scanning speed and powder feed rate governs the formation characteristics and microhardness evolution of the coating. The experiment verified that the prediction error for the optimal parameters is controlled within 5%, demonstrating good engineering applicability. Further analysis indicates that grain refinement and the formation of strengthening phases in the optimal coating are the key mechanisms behind the significant improvement in hardness and wear resistance, and the coating primarily exhibits a mild abrasive wear mechanism. This work realizes the multi-objective optimization of the high-speed laser cladding process via RSM and DE-NSGA-II algorithm, which provides a novel and efficient method for parameter optimization and engineering application of high-speed laser cladding. Full article

(This article belongs to the Section Metal Surface Process)

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24 pages, 59787 KB

Open AccessArticle

Compressive Properties of Rammed Earth at Ming Great Wall Sites in Northwest China: Effects of Material Sourcing and Rammed Technology

by Chengrui Ge, Kai Cui, Xiangyu Wen and Pengfei Xu

Coatings 2026, 16(5), 580; https://doi.org/10.3390/coatings16050580 (registering DOI) - 11 May 2026

Abstract

Heritage rammed earth is a special soil material formed by manually selecting and ramming locally available Quaternary surface deposits layer by layer. However, the quantitative influence of material sourcing and rammed technology on the compressive properties of heritage rammed earth remains insufficiently understood, [...] Read more.

Heritage rammed earth is a special soil material formed by manually selecting and ramming locally available Quaternary surface deposits layer by layer. However, the quantitative influence of material sourcing and rammed technology on the compressive properties of heritage rammed earth remains insufficiently understood, which limits the mechanical assessment and conservation planning of rammed earth sites. In this study, undisturbed rammed earth from 15 Ming Great Wall sites in Northwest China was investigated. Field 3D scanning, particle-size analysis, uniaxial compression testing, mesoscopic structural observation, and DEM analysis were combined to evaluate the effects of material characteristics and rammed technology on the compressive properties of heritage rammed earth. The results show clear regional differences in material characteristics and rammed technology parameters across the 15 sites. Across the five occurrence regions from the Extremely Arid Area to the Semi-Humid Area, dry density, silt fraction, curvature coefficient, and ramming pit distribution area ratio generally decreased, whereas clay and colloidal particle fraction,

d_{60}

,

C_{u}

, and rammed modulus generally increased. These variations were accompanied by changes in internal fabric, including aggregate proportion, coordination-number difference, high-stress particle proportion, and force-chain particle proportion. The peak stress and failure strain ranged from 0.48 to 1.01 MPa and from 0.03 to 0.07, respectively. Both parameters showed a decreasing regional trend from the extremely arid area to the semi-humid area, following the sequence: extremely arid area, arid area, semi-arid area, cold and humid area, and semi-humid area. From the Extremely Arid Area to the Semi-Humid Area, the shear failure mode changed from single-fork to mixed double-fork and then to intersecting double-fork. Regression analysis further showed that material and rammed technology parameters were closely related to mesoscopic structural parameters, with R² values generally greater than 0.75. These findings suggest that the regional differences in compressive behavior were closely associated with variations in material sourcing, rammed technology, internal fabric, and the load-bearing structure of rammed earth. Full article

(This article belongs to the Special Issue Advanced Manufacturing for Architected Materials and Multifunctional Coatings)

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20 pages, 2553 KB

Open AccessArticle

Wet Chemical Synthesis of Benzalkonium Chloride-Hectorite Composites: Structural Regulation and Enhanced Antibacterial/Antifungal Performance for Indoor High-Humidity Decorative Materials

by Changchun Liu, Feng Yang, Wenkang Zhang, Feiya Shi, Shirong Xu, Taotao Yu, Jin Cheng, Ruize Chen, Chen Fang, Guping Tang, Hong Sun and Kenji Ogino

Coatings 2026, 16(5), 579; https://doi.org/10.3390/coatings16050579 (registering DOI) - 11 May 2026

Abstract

To mitigate health hazards from pathogenic bacteria (Escherichia coli, Staphylococcus aureus) and fungi (Aspergillus niger) as well as the coating mildew issue in high-humidity indoor environments, and to overcome the challenges of particle agglomeration and non-uniform distribution in [...] Read more.

To mitigate health hazards from pathogenic bacteria (Escherichia coli, Staphylococcus aureus) and fungi (Aspergillus niger) as well as the coating mildew issue in high-humidity indoor environments, and to overcome the challenges of particle agglomeration and non-uniform distribution in conventional benzalkonium chloride (BAC)-clay composites, this study proposes a wet chemical strategy to prepare BAC-hectorite antimicrobial composites using synthetic hectorite as a high-performance carrier, which is superior to natural clays such as montmorillonite and kaolin in structural uniformity, ion-exchange efficiency, and dispersion stability. Characterization using X-ray diffraction (XRD), scanning electron microscopy (SEM), Fourier transform infrared spectroscopy (FTIR), and Brunauer–Emmett–Teller (BET) analysis confirmed the successful intercalation of BAC cations into the hectorite interlayers through ion exchange. This resulted in a significant expansion of the interlayer spacing from 1.0–1.2 nm to 1.5–1.8 nm, a marked alleviation of particle agglomeration, and an optimized pore structure. A clear structure–activity relationship between preparation conditions, microstructure regulation, and antimicrobial performance is systematically established. Antibacterial tests revealed superior efficacy against Gram-positive bacteria; the composite exhibited an inhibition zone of 13.31 mm and a minimum inhibitory concentration (MIC) of 4 μg/mL against S. aureus, compared to 11.62 mm and 32 μg/mL against E. coli. Practical application tests demonstrated that at an ultralow addition level of 0.4%, incorporating this composite into latex paint achieved an antibacterial rate exceeding 99.9% against both pathogens. When added to putty powder, it yielded Grade 0 mold resistance with no observable growth. Furthermore, compounding with polypropylene (PP) increased the elongation at break to approximately 600%, simultaneously realizing antibacterial, antifungal, and toughening functions, thereby not only conferring antibacterial functionality but also significantly enhancing toughness—resolving the typical polymer embrittlement caused by traditional inorganic antibacterial fillers. Short-term evaluations confirm that this composite offers a stable structure, high-efficiency antimicrobial properties, and improved substrate mechanics at low loading levels. These findings provide technical support and experimental guidance for the functional upgrading of indoor decorative coatings, putties, and polymer materials used in high-humidity scenarios such as kitchens and bathrooms. Full article

(This article belongs to the Special Issue Advanced Functional Coatings: Synthesis, Characterization, and Multifunctional Applications in Energy, Antimicrobial, and Corrosion Resistance)

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19 pages, 4131 KB

Open AccessArticle

Performance Evolution of Rubber–Plastic-Based Elastomer-Modified Asphalt Under Different Aging Conditions

by Wenxiang Xie, Jiayan Fan, Yuetan Ma, Yixiang Chen, Qingkui Han, Liuyang Zhang, Jun Cai, Zuxun Ding and Tangxin Xie

Coatings 2026, 16(5), 578; https://doi.org/10.3390/coatings16050578 (registering DOI) - 11 May 2026

Abstract

To reveal the long-term anti-aging mechanisms of rubber–plastic elastomer-modified asphalt in complex service environments and overcome the inherent defects of single polymer modifiers—namely their susceptibility to degradation or phase separation—this study prepared styrene-butadiene-styrene (SBS), low Mooney rubber (LMMR), and low-density polyethylene (LDPE)-modified asphalts. [...] Read more.

To reveal the long-term anti-aging mechanisms of rubber–plastic elastomer-modified asphalt in complex service environments and overcome the inherent defects of single polymer modifiers—namely their susceptibility to degradation or phase separation—this study prepared styrene-butadiene-styrene (SBS), low Mooney rubber (LMMR), and low-density polyethylene (LDPE)-modified asphalts. Simultaneously, an LMMR-LDPE rubber–plastic thermoplastic elastomer (TPE) was fabricated utilizing twin-screw extrusion technology and subsequently used to prepare a composite-modified asphalt. Three aging protocols were simulated: short-term thermo-oxidative aging (RTFOT), long-term pressure aging (PAV), and ultraviolet light aging (UV). A multi-scale quantitative characterization was conducted using a dynamic shear rheometer, Fourier transform infrared spectroscopy, and atomic force microscopy to evaluate the rutting factor, carbonyl index, and surface microroughness of each system before and after aging. The experimental results indicate that the coupled effect of long-term stress and thermal oxidation causes the most severe damage to the colloidal structure of modified asphalt. Conventional SBS-modified asphalt, due to its abundance of unsaturated double bonds, exhibits a sharp increase in the carbonyl index and aging index of the rutting factor after aging, making it highly susceptible to oxidative chain scission. Although LDPE-modified asphalt possesses chemical inertness, it is prone to crystalline phase separation under aging conditions, resulting in a microroughness distortion rate of up to 86.36%. In contrast, the LMMR-LDPE composite system, leveraging the high chemical stability of the saturated aliphatic carbon chain and the flexibility-enhancing and crystallization-inhibiting effects of LMMR, effectively reduces active oxidation sites and improves interfacial compatibility. This composite system exhibits the lowest carbonyl increment and rheological attenuation under all aging conditions, while effectively inhibiting the free migration and agglomeration of macromolecular components. The LMMR-LDPE composite modification technology effectively overcomes the inherent drawbacks of single polymers, such as susceptibility to degradation or segregation, demonstrating excellent long-term macroscopic rheological stability and microscopic phase morphology anti-aging capability. The present findings provide laboratory-scale mechanistic support for the design of durable rubber–plastic-modified asphalt systems, while further pilot-scale, economic, and field validation is still required before practical engineering application can be fully assessed. Full article

(This article belongs to the Special Issue Advances in Pavement Materials and Civil Engineering—2nd Edition)

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3 pages, 1685 KB

Open AccessCorrection

Correction: Guo et al. Preparation and Performance Study of Sand-Containing Hollow Concrete with Alkali-Activated Recycled Concrete Powder Based on Target Porosity. Coatings 2026, 16, 313

by Yuanxin Guo, Wenna Li, Zhizhu Zhang, Gongbing Yue, Xingang Xu, Qiuyi Li, Changhai Shao and Mingxu Chen

Coatings 2026, 16(5), 577; https://doi.org/10.3390/coatings16050577 (registering DOI) - 11 May 2026

Abstract

In the original publication [...] Full article

(This article belongs to the Section Surface Characterization, Deposition and Modification)

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26 pages, 73675 KB

Open AccessArticle

The Biocolonization Control Mechanism of Traditional Raw Earth–Rubble Walls in Fuzhou

by Muye Guan, Rui Zhu, Yuhong Ding, Li Chen, Jingwei Liang, Qingnian Deng and Ruiming Guan

Coatings 2026, 16(5), 576; https://doi.org/10.3390/coatings16050576 (registering DOI) - 11 May 2026

Abstract

Focusing on the R&D demand for green earthen building materials in coastal high-temperature and high-humidity areas, this study explores the biocolonization control mechanism of raw earth–rubble walls, taking the traditional raw earth–rubble walls of ancient buildings in Sanfang Qixiang, Fuzhou, as the research [...] Read more.

Focusing on the R&D demand for green earthen building materials in coastal high-temperature and high-humidity areas, this study explores the biocolonization control mechanism of raw earth–rubble walls, taking the traditional raw earth–rubble walls of ancient buildings in Sanfang Qixiang, Fuzhou, as the research subject. FTIR, XRD, Raman, and SEM-EDS combined technologies were employed for characterization. The results show that the raw earth is rich in proteins, amino acids, and other nutrients, which provide the nutritional basis for plant growth. The raw earth and rubble share homologous mineral components. The rubble is fired from raw earth mixed with iron minerals such as hematite, with carbonaceous substances generated during the firing process. Iron, carbon, and potassium released from the weathered rubble may inhibit the growth of plant roots. The raw earth is relatively looser than the rubble, and the two form a dense–loose alternating structure. Combined with the secondary calcification mechanism in the raw earth, this structure resists the expansion and cracking of the wall and improves the viscosity and hardness of the wall. It is concluded that in a high-temperature and high-humidity environment, the raw earth first releases nutrients to promote plant growth. As time progresses, the relevant substances released by the rubble continuously inhibit root growth. Combined with the structural characteristics of the wall with high firmness and crack resistance, plants growing on the wall will not damage the wall structure. This finding provides a theoretical basis for the biocolonization control mechanism of raw earth–rubble walls and also offers practical references for the protection and sustainable reuse of raw earth buildings in similar areas. Full article

(This article belongs to the Special Issue New Insights into Everyday Heritage: Surface Analysis and Conservation)

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33 pages, 16984 KB

Open AccessReview

Fabrication of Protective Surface Layers on Tungsten for Plasma-Facing Material Application in Fusion Reactors: Research Progress from a Process Technology View

by Kunjie Luo, Bingchen Huang, Shuiyong Wang, Wanxiang Zhao, Naiming Lin, Maolin Li, Rui Wang, Yuxin Fan, Chenqing Lei, Zeyu Sun, Luwei Xue and Dongyang Li

Coatings 2026, 16(5), 575; https://doi.org/10.3390/coatings16050575 (registering DOI) - 9 May 2026

Abstract

The development of fusion technology requires materials that can withstand heat, erosion, and activation at the edge of fusion plasma. Thanks to its high melting point, superior thermal conductivity, and excellent resistance to sputtering and retention, tungsten (W) has been regarded as the [...] Read more.

The development of fusion technology requires materials that can withstand heat, erosion, and activation at the edge of fusion plasma. Thanks to its high melting point, superior thermal conductivity, and excellent resistance to sputtering and retention, tungsten (W) has been regarded as the leading candidate for the plasma-facing materials (PFMs) of the main chambers and divertors in controlled thermonuclear fusion reactors. Nevertheless, W-PFMs are prone to complex severe surface deterioration under extreme service conditions during operation in fusion reactors. This includes physical/chemical sputtering, which results in material loss and plasma contamination; He-induced blistering and fuzz formation, which reduce thermal conductivity by several orders of magnitude; thermal fatigue cracking caused by transient loads; and neutron irradiation embrittlement, which leads to hardening, swelling, and loss of ductility. To overcome these issues while maintaining core thermophysical properties, protective surface layers have been fabricated primarily via chemical vapor deposition (CVD), physical vapor deposition (PVD), and spray and plasma-based surface modification technologies. This review assesses the recent progress in the fabrication of protective surface layers on W for PFM application in fusion reactors from a technical perspective, thereby offering new insights that advance the feasibility of fusion reactors and accelerating the practical realization of sustainable fusion energy systems. Full article

(This article belongs to the Special Issue Microstructural Evolution and Mechanical Behavior of High-Entropy Alloy Coatings)

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