Your search keyword '"Nanocoatings"' showing total 1,494 results

1. Electrochromic glazing with nanocoating integration impact on building energy efficiency: Bibliometric analysis (1983–2023)

Author

Aldawoud, Abdelsalam, Husein, Lama Alhaj, and Mushtaha, Emad S.

Published

2025

2. Full-scale assessment of a liquid CsWO3-SnO2 near-infrared shielding coating and a nanoceramic WO3 photochromic window film for in-situ window retrofits

Author

Khaled, Khaled and Berardi, Umberto

Published

2025

3. Nanomaterials in aquaculture disinfection, water quality monitoring and wastewater remediation

Author

Silvanir, Foo, Wei Han, Chia, Wen Yi, Ende, Stephan, Chia, Shir Reen, and Chew, Kit Wayne

Published

2024

4. Anticorrosive two-dimensional heterostructured nanocoatings self-assembled on steel with multiple desired merits.

Author

Ye, Chen, Tian, Qichen, She, Yuanbin, Zhu, Yangguang, Dai, Dan, Wu, Mengfan, Yan, Qingwei, Chu, Wubo, Cai, Tao, Gui, Xuchun, Yu, Jinhong, Li, He, Jiang, Nan, Zhao, Wenjie, Huang, Liang-Feng, Fu, Li, and Lin, Cheng-Te

Subjects

*INTERFACIAL reactions, *BORON steel, *ELECTROLYTIC corrosion, *NANOCOATINGS, *CORROSION potential, *BORON nitride

Abstract

[Display omitted] • Graphene and h-BN nanosheets was self-assembled on stainless steel to create stable heterostructured 2D nanocoatings. • These ultrathin 2D nanocoatings (< 30 nm) showed excellent corrosion resistance, with mechanisms revealed by electrochemical tests. • The nanocoatings offer multiple benefits like preventing reactions, labyrinth effect, curbing galvanic corrosion, and easing stress. In this study, an economic and controllable Marangoni self-assembly approach is designed to prepare the heterostructured nanocoatings (8–28 nm) consisting of alternately stacked mosaic nanosheets of hexagonal boron nitride (h -BN) and graphene. The resulting 2D nanocoatings exhibit a combination of advantageous properties, such as prevention of interfacial reactions, robust interfacial binding, a labyrinthine barrier effect, inhibition of galvanic corrosion, and alleviation of internal stress. The protective property of graphene/ h -BN heterostructured nanocoatings is studied through potentiodynamic polarization curves and electrochemical impedance spectroscopy, with the theoretical support of first-principles calculations. The corrosion current density of ≈28 nm-thick graphene/ h -BN multilayer coated stainless steel is 1.82 × 10−8 A cm−2, which decreases by an order of magnitude compared to that of an uncoated one, meanwhile, the corrosion potential increases from −0.192 to 0.023 V (increase: ≈0.215 V). The enhancement of anticorrosion performance of heterostructured nanocoatings can be attributed to the labyrinth barrier effect associated with highly ordered horizontal arrangement, effective coverage of metal substrates by mosaic multilayers, and suppressed galvanic corrosion effect by insulating BNNS monolayers. This study can shed much light on the effective solution of many stubborn issues confronted by the development of anticorrosive 2D nanocoatings. [ABSTRACT FROM AUTHOR]

Published

2025

5. Manipulation of biophysicochemical behavior of transporters using nanodimensional coating.

Author

Dholakia, Jheel, Prabhakar, Bala, Bajaj, Jay, and Shende, Pravin

Subjects

*NANOCOATINGS, *MEDICAL equipment, *DRUG coatings, *CARBON compounds, *SURFACE coatings

Abstract

Nanocoating is a layer or coating on various drug delivery systems and medical devices within the nanometer range to improve the physicochemical properties, stability, compatibility and protect the materials from the external environment. The categories of materials used for the coating include polymers, metals, and carbon compounds. The technology is used for pharmaceutical as well as non-pharmaceutical areas. Nanocoating possesses some disadvantages and the need to use specialized instruments. Nanotechnology is beneficial from the developmental stages of the formulations to the finalized products and is one of the important methods to improve the efficiency of pharmaceutical products. [ABSTRACT FROM AUTHOR]

Published

2025

6. Recent advances in emerging integrated anticorrosion and antifouling nanomaterial-based coating solutions.

Author

Thomas, Paul, Sahoo, Bichitra Nanda, Thomas, Peter James, and Greve, Martin Møller

Subjects

COMPOSITE coating, PHYSICAL & theoretical chemistry, NANOCOATINGS, MATERIALS science, FOULING

Abstract

The rapid progress in the marine industry has resulted in notable challenges related to biofouling and surface corrosion on underwater infrastructure. Conventional coating techniques prioritise individual protective properties, such as offering either antifouling or anticorrosion protection. Current progress and innovations in nanomaterials and technologies have presented novel prospects and possibilities in the domain of integrated multifunctional coatings. These coatings can provide simultaneous protection against fouling and corrosion. This review study focuses on the potential applications of various nanomaterials, such as carbon-based nanostructures, nano-metal oxides, polymers, metal–organic frameworks, and nanoclays, in developing integrated multifunctional nano-based coatings. These emerging integrated multifunctional coating technologies recently developed and are currently in the first phases of development. The potential opportunities and challenges of incorporating nanomaterial-based composites into multifunctional coatings and their future prospects are discussed. This review aims to improve the reader's understanding of the integrated multifunctional nano-material composite coating design and encourage valuable contributions to its development. [ABSTRACT FROM AUTHOR]

Published

2024

7. Advancing surface safety: the role of sol-gel nanocoatings in the context of MIRIA European project.

Author

Bezzon, Alessia, Aurisicchio, Luigi, Castlunger, Evelyn, Martellini, Tommaso Ceccatelli, Czerwiński, Dominik, Favuzzi, Ilaria, Jeremiasz, Olgierd, Meduri, Angelo, Mosinger, Jiří, Kurylak, Witold, Motellier, Sylvie, Nedéus, Henric, Rabilloud, Thierry, Rossi, Edoardo, Royo, Patricia, Sorsa, Petri, Söyrinki, Saara, and Tului, Mario

Abstract

Among the challenges posed by the COVID-19 pandemic, significant efforts have been undertaken to develop antimicrobial/antiviral surfaces by exploiting coating solutions. In this article, we review the actions undertaken by the EU project MIRIA, the main one being the reduction of pathogen transmission on high-traffic surfaces in public and healthcare environments. The project implements several synergies from key antimicrobial/antiviral element selection to the grafting of complex-shaped surfaces. The focus is given to one of the project's key strategies: the adoption of sol-gel technology, known for its efficiency in creating versatile, cost-effective coatings suitable for a wide range of substrates. The project rigorously tests the coatings in simulated environments, such as operating theatres, ensuring their effectiveness and safety. This includes comprehensive durability testing against environmental, chemical, and mechanical stresses, guaranteeing the coatings' long-term functionality. MIRIA's validation process encompasses antibacterial, antifungal, and antiviral testing in line with international standards, confirming their broad-spectrum pathogen resistance. Along with this overview, the impact of the initiative is elucidated, extending beyond healthcare, enhancing public health, creating safer living, and working environments, and reducing economic losses due to illness. To this, the MIRIA project is expected to significantly contribute to the European research and innovation in antimicrobial coatings, addressing challenges like scalability and efficacy against various pathogens. The emphasis on sustainable synthesis, including bio-based materials which align with ecological goals, positions MIRIA as a pivotal initiative in enhancing health safety standards and resilience across Europe. Highlights: The MIRIA project goal is to avoid cross contamination in high traffic objects in the health field. The strategy is the development of 99.99% effective antimicrobial nanocoatings. MIRIA makes use of sol-gel for its versatility on multiple surfaces and on-site application. Standardized testing will ensure non-toxic, antimicrobial and durability properties. One of the pathogens considered is COVID-19, to enhance readiness for future pandemics. [ABSTRACT FROM AUTHOR]

Published

2024

8. 抗紫外多功能涂层改性芳纶的研究进展.

Author

杨祉祺, 杨晨光, 王雯雯, 刘 娜, and 严 坤

Subjects

ARAMID fibers, CHEMICAL structure, FIREPROOFING agents, NANOCOATINGS, SURFACE coatings

Abstract

Copyright of China Synthetic Fiber Industry is the property of Sinopec Baling Petrochemical Company and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

9. Nanocoating of lactic acid bacteria: properties, protection mechanisms, and future trends.

Author

Fan, Qing, Zeng, Xiaoqun, Wu, Zhen, Guo, Yuxing, Du, Qiwei, Tu, Maolin, and Pan, Daodong

Subjects

*METALLIC bonds, *LACTIC acid bacteria, *NANOCOATINGS, *BIOMEDICAL materials, *SURFACE coatings

Abstract

Lactic acid bacteria (LAB) is a type of probiotic that may benefit intestinal health. Recent advances in nanoencapsulation provide an effective strategy to protect them from harsh conditions via surface functionalization coating techniques. Herein, the categories and features of applicable encapsulation methods are compared to highlight the significant role of nanoencapsulation. Commonly used food-grade biopolymers (polysaccharides and protein) and nanomaterials (nanocellulose and starch nanoparticles) are summarized along with their characteristics and advances to demonstrate enhanced combination effects in LAB co-encapsulation. Nanocoating for LAB provides an integrity dense or smooth layer attributed to the cross-linking and assembly of the protectant. The synergism of multiple chemical forces allows for the formation of subtle coatings, including electrostatic attractions, hydrophobic interactions, π–π, and metallic bonds. Multilayer shells have stable physical transition properties that could increase the space between the probiotic cells and the outer environment, thus delaying the microcapsules burst time in the gut. Probiotic delivery stability can be promoted by enhancing the thickness of the encapsulated layer and nanoparticle binding. Maintenance of benefits and minimization of nanotoxicity are desirable, and green synthesized nanoparticles are emerging. Future trends include optimized formulation, especially using biocompatible materials, protein or plant-based materials, and material modification. [ABSTRACT FROM AUTHOR]

Published

2024

10. Smart Nanocoating‐ an Innovative Solution to Create Intelligent Functionality on Surface.

Author

Dhiman, Nitesh and Singla, Nancy

Subjects

*NANOCOATINGS, *MICROBIAL adhesion, *TECHNOLOGICAL innovations, *EVIDENCE gaps, *ENVIRONMENTAL monitoring

Abstract

The interaction of substrate surfaces with the environment (moisture, heat, pressure, chemicals) has cascade effects on their efficiency, performance, durability due to their susceptibility towards microbial adhesion, spontaneous leaching, impairment, corrosion etc. Many scientific, technological innovations such as smart coating have been discovered for the protection of these surfaces. It is a high‐tech, high value coating capable of responding to environmental impulses. Incorporation of nanofillers, nanomatrices in smart coating improve surface performance by extending service life, provide high durability, high physical coverage, adhesive strength etc. Real‐time monitoring of environmental conditions, structural health could be made possible by sensing coatings. This review predominantly highlights the essential features, design, advancements, applications of smart nanocoatings over elementary nanocoatings. To cover the whole study, drawbacks of traditional coating methods are also discussed. Finally, the research gaps, future perspectives of smart nanocoatings will be overlooked. [ABSTRACT FROM AUTHOR]

Published

2024

11. Route to Measure Exact Parameters of Bio-Nanostructures Self-Assembly.

Author

Kryuchkov, Mikhail, Valnohova, Jana, and Katanaev, Vladimir L.

Subjects

*DISPERSION relations, *RATE coefficients (Chemistry), *SYNTHETIC biology, *NANOCOATINGS, *NANOTECHNOLOGY

Abstract

Artificial bio-nanocoatings, primarily composed of proteins, offer a broad range of applications across various fields thanks to their unique properties. Proteins, as major components of these structures, enable a high degree of customization, such as mutations, conjugation with other molecules or nanoparticles, or the inclusion of an enzymatic activity. Their ability to self-assembly simplifies the production of bio-nanocoatings, making this process efficient and environment-friendly. Despite these advantages, a comprehensive understanding of the underlying self-assembly mechanism is lacking, and the reaction rates governing this process have not been characterized. In this article, we introduce a novel method to determine the key parameters describing the self-assembly mechanism of bio-nanostructures. For the first time, this approach enables an accurate calculation of the autocatalytic and self-inhibitory parameters controlling the process. Through mathematical modeling, our method enhances the understanding of how the protein-based nanocoatings form and opens new avenues for their application in nanotechnology and synthetic biology. Improved control over the self-assembly processes may enable the development of nanomaterials optimized for specific functions, such as drug delivery, biosensing, and bioactive surface fabrication. [ABSTRACT FROM AUTHOR]

Published

2024

12. Polydopamine nanocoating to use surface functionalization of polypropylene fabrics with a closed structure.

Author

TELLI, ABDURRAHMAN and ARABACI, SAFIYE

Subjects

NONWOVEN textiles, COATED textiles, NANOCOATINGS, SCANNING electron microscopy, DOPAMINE

Abstract

Copyright of Industria Textila is the property of Institutul National de Cercetare-Dezvoltare pentru Textile si Pielarie and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

13. Near-infrared remote triggering of bio-enzyme activation to control intestinal colonization by orally administered microorganisms.

Author

Sun, Wei, Yun, Fu, Guo, Qinglu, Guo, Hao-Lin, Li, Bowen, Feng, Guoqing, Cao, Jimin, Bai, Yang, Zheng, Bin, and Ruan, Xianhui

Subjects

COLONIZATION (Ecology), NANOCOATINGS, BIOTHERAPY, SECRETION, POLYMERS, PROBIOTICS, CELLULASE, CARBOXYMETHYLCELLULOSE

Abstract

Oral biotherapeutics hold significant promise, but their lack of controllability and targeting poses a major challenge, particularly for intestinal bacterial biotherapeutics. In response, we have developed a nanoencapsulation approach that responds to the release of enzyme activity in the organism and activates the enzyme in situ, allowing for controlled colonization of microbes in the gut. The nano-coating comprises a two-layer structure: an inner layer of polydopamine with photothermal and adhesive properties, and an outer layer of gelatin–sodium carboxymethylcellulose, which is hydrolyzed by cellulases in the gut following photothermal interaction with dopamine. We have successfully achieved controlled colonization of a wide range of microorganisms. Furthermore, in a diabetes model, this approach has had a profound impact on regulating glucagon-like peptide-1 (GLP-1) production, β-cell physiology, and promoting insulin secretion. This nanocoating is achieved by in situ activation of cellulase without the need for genetic or targeted molecular modification, representing a new paradigm and alternative strategy for microbial therapy. It not only enables precise and controlled colonization of probiotics but also demonstrates great potential for broader application in the field of oral biotherapy. We have developed a nano-encapsulation method that triggers enzyme activity in response to enzymatic activity, resulting in the controlled release and adhesion of a wide range of microorganisms in the gut. The nano coating comprises two layers: an inner layer of polydopamine with photothermal and adhesion properties, and an outer layer of a gelatin-sodium carboxymethylcellulose polymer, which can be hydrolyzed by cellulases in the intestine. Additionally, this method allows for the preparation of various microbial coatings. This approach holds significant promise for regulating GLP-1 production, the physiological function of pancreatic β-cells, and promoting insulin secretion in diabetes models. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

14. Tribological Properties of Multilayer DLC/MoS 2 Nanocomposite Coatings on Microtextured Titanium Alloy Surfaces.

Author

Liu, Ke, Ding, Qingqing, Peng, Hao, Guan, Kang, Xi, Xiaowan, Kong, Ning, and Liao, Maolin

Subjects

COMPOSITE coating, NANOCOATINGS, SURFACE coatings, SURFACE texture, MAGNETRON sputtering

Abstract

Single surface texture or coating technology is gradually unable to produce lasting lubrication of a TC4 titanium alloy in a harsh environment. In order to address this problem, a rectangular microstructure is prepared on the surface of a TC4 titanium alloy by laser processing, and then MoS2/DLC composite interlayer nanocoatings are prepared on the surface by non-equilibrium magnetron sputtering. Friction and wear tests are then carried out on single fabricated, coated and fabricated coatings. The results show that the MoS2/DLC composite interlayered nanocoating can effectively combine with the texture to achieve better friction reduction compared with the single texture and coating. The textured composite coating has the lowest friction coefficient (reduced from 0.4122 to 0.0978) and wear. Through controlled experiments, the textured coating showed good tribological properties at different temperatures and in different friction cycle tests. This study can effectively improve the tribological properties of metal materials through composite coatings, providing research ideas for enhancing the service life of alloys under long-term friction in high-temperature environments. [ABSTRACT FROM AUTHOR]

Published

2024

15. Bioorthogonal conjugation and responsive nanocoating of probiotics for inflammatory bowel disease.

Author

Peng, Pandi, Feng, Tao, Yang, Xue, Ding, Rui, Wang, Junru, Chen, Pengyu, Guo, Yuxin, and Li, Peng

Subjects

*INFLAMMATORY bowel diseases, *ORAL drug administration, *GUT microbiome, *NANOCOATINGS, *PROBIOTICS, *ESCHERICHIA coli

Abstract

Inflammatory bowel disease (IBD) is closely associated with dysregulated immune response, gut mucosal barrier, and microbiota. Conventional treatments suffer from inferior bioavailability and inadequate efficiency. Herein, we present a synergistic therapeutic strategy based on multifunctionalized probiotics to mitigate IBD through single oral administration. The probiotic (Escherichia coli Nissle 1917) is bioorthogonally conjugated with immunomodulators and subsequently encapsulated by an enteric coating. The viability and bioactivity of probiotics are not affected by the modifications. And the armored probiotics are able to resist the harsh environment of the stomach and shed their enteric coating in the intestinal tract, exposing immunomodulators to polarize pro-inflammatory M1-type macrophages into anti-inflammatory M2-type. In a mouse colitis model, orally administered multifunctionalized probiotics cooperatively alleviate IBD with increased body weight to 1.13 folds and decreased disease activity index to 0.43 folds, through downregulating the pro-inflammatory cytokines expression, upregulating the epithelial tight junction-associated proteins levels to restore the intestinal barrier, and increasing the microbiota richness and abundance. This work exhibits a feasible approach to construct functionalized orally administered probiotics for enhanced synergistic therapy of IBD. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

16. Surface engineering of nickel-rich single-crystal layered oxide cathode enables high-capacity and long cycle-life sulfide all-solid-state batteries.

Author

Xuebao Li, Jiasen Wang, Cheng Han, Kun Zeng, Zhuangzhi Wu, and Dezhi Wang

Subjects

SOLID electrolytes, ENERGY density, LITHIUM cells, LITHIUM-ion batteries, NANOCOATINGS

Abstract

Sulfide all-solid-state lithium batteries (SASSLBs) with a single-crystal nickel-rich layered oxide cathode (LiNixCoyMn1-x-yO2, x ≥ 0.8) are highly desirable for advanced power batteries owing to their excellent energy density and safety. Nevertheless, the cathode material's cracking issue and its severe interfacial problem with sulfide solid electrolytes have hindered the further development. This study proposes to employ surface modification engineering to produce B-NCM cathode materials coated with boride nanostructure stabilizer in situ by utilizing NCM encapsulated with residual lithium. This approach enhances the electrochemical performance of SASSLBs by effectively inhibiting electrochemical-mechanical degradation of the NCM cathode material on cycling and reducing deleterious side reactions with the solid sulfide electrolyte. The B-NCM/LPSCl/Gr SASSLBs demonstrate impressive cycling stability, retaining 84.19 % of its capacity after 500 cycles at 0.2 C, which represents a 30.13 % increase vs. NCM/LPSCl/Gr. It also exhibits a specific capacity of 170.4 mAh/g during its first discharge at 0.1 C. This work demonstrates an effective surface engineering strategy for enhancing capacity and cycle life, providing valuable insights into solving interfacial problems in SASSLBs. [ABSTRACT FROM AUTHOR]

Published

2024

17. A novel carbon nanohorn-based intumescent multilayer nanocoating on cotton fabrics: thermal degradation kinetics, flammability and flame-retardant mechanism.

Author

Xu, Jie, Liu, Xiangrong, Yao, Xuehui, Xue, Manman, Chen, Liqing, Guo, Fanhui, Zhang, Yixin, Xie, Zhipeng, Liang, Feng, and Wu, Jianjun

Subjects

*COTTON textiles, *FIREPROOFING, *FIREPROOFING agents, *NANOCOATINGS, *FLAMMABILITY, *MELAMINE, *FLAME spraying

Abstract

Creating eco-friendly flame retardants (FRs) that are highly effective for textiles while requiring minimal quantities is crucial for both human well-being and environmental conservation. Traditionally, halogen FRs have been the mainstay in this field. Yet, due to their harmful impacts on both human health and the environment, there is a growing demand to discontinue their use. Herein, in this work, a novel eco-friendly intumescent-based flame retardant for cotton fabrics, consisting of ammonium polyphosphate (APP), single-walled carbon nanohorns (SWCNHs), and melamine (MEL) was explored. The addition of SWCNHs demonstrated a clear synergistic effect with APP and MEL in enhancing the flame retardancy of cotton fabrics. After four spraying cycles, the treated cotton fabric ASM4 demonstrated outstanding flame retardancy and self-extinguishing properties. Additionally, its LOI value could reach 24.1 ± 0.1% and the damage length dropped to 4.6 ± 0.2% cm from 30.0 ± 0.1% cm for the pristine cotton fabric, while preserving its original morphology with partial carbonization. The pHRR and THR of ASM4 were dramatically decreased by 90% and 51%, respectively in the cone calorimeter test. Moreover, investigating the thermal degradation kinetics of treated cotton fabric and the physicochemical properties of the char residues revealed the crucial influence of SWCNHs on improving the flame resistance of cotton fabrics. The incorporation of SWCNHs improved both the thermal stability and the degree of graphitization of the char layer, which served as a protective barrier. This barrier efficiently blocked the release of volatile combustible substances while allowing for the emission of nonflammable gases. This work provides a theoretical basis for the feasible application of SWCNHs in intumescent FRs. [ABSTRACT FROM AUTHOR]

Published

2024

18. Tailoring Tribological Characteristics in Titanium Alloys by Laser Surface Texturing and 2D Ti3C2Tx MXene Nanocoating.

Author

Zhang, Qicheng, Li, Yong, Liang, Fei, Zhang, Haoran, Wang, Bin, Li, Xiaopeng, Lin, Zifeng, Lin, Yan, and Chen, Xiang

Subjects

*STRAIN hardening, *SURFACE texture, *SUBSTRATES (Materials science), *NANOCOATINGS, *WEAR resistance

Abstract

The inferior tribological properties of titanium (Ti) and its alloys, due to their limited work hardening capability and the mechanical instability of their oxide scale, pose substantive challenges in practical applications. Surface texturing and the application of 2D material coatings are acknowledged as efficacious strategies for enhancing these properties. Nevertheless, the rapid loss of effectiveness when employing these methods in isolation highlights a significant limitation. Herein, a 50‐nm‐thick MXene nanocoating is deposited onto groove‐textured pure Ti surface, effectuating a reduction in the coefficient of friction (COF) from ≈0.57 to 0.17, thereby substantially mitigating wear on the Ti substrate. The grooved surface architecture plays a vital role in storing MXenes and facilitating lubricant replenishment through the stirring effect of frictional stress during subsequent friction process. Further, the continuous decomposition and reorganization of MXene coating results in the formation of a robust tribofilm that resists oxidation and plastic deformation in the subsurface layer, markedly enhancing the friction and wear resistance. These findings are crucial for improving tribological performance in Ti and its alloys and provide a straightforward yet effective strategy for tailoring their tribological properties by integrating LST with 2D material nanocoating. [ABSTRACT FROM AUTHOR]

Published

2024

19. An Overview of Nanotechnology in Dental Medicine.

Author

Nicolae, Carmen-Larisa, Pîrvulescu, Diana-Cristina, Niculescu, Adelina-Gabriela, Rădulescu, Marius, Grumezescu, Alexandru Mihai, and Croitoru, George-Alexandru

Subjects

TARGETED drug delivery, NANOSTRUCTURED materials, BONE regeneration, DENTAL care, DENTISTRY, DRUG delivery systems

Abstract

The dentistry industry has been modernized by nanotechnology, as this emerging field has opened up new doors for dental treatment, restoration, and tissue regeneration. The potential applications of nanomaterials in dentistry are reviewed in this paper, ranging from advanced restorative materials to targeted drug delivery systems. Due to their unique characteristics (e.g., high surface area-to-volume ratios and tunable physicochemical properties), nanomaterials allow for the precise control of material behavior at the nanoscale. The ability of nanostructured materials to promote tissue regeneration offers the prospect of developing new approaches in bone and periodontal regeneration. Therefore, this review thoroughly analyzes nanomaterials' characteristics and biomedical applications, highlighting how they can aid in overcoming challenges in dental care and create possibilities for more individualized and less-invasive dental treatments. [ABSTRACT FROM AUTHOR]

Published

2024

20. Comparison of Key Properties of Ag-TiO 2 and Hydroxyapatite-Ag-TiO 2 Coatings on NiTi SMA.

Author

Dudek, Karolina, Strach, Aleksandra, Wasilkowski, Daniel, Łosiewicz, Bożena, Kubisztal, Julian, Mrozek-Wilczkiewicz, Anna, Zioła, Patryk, and Barylski, Adrian

Subjects

ESCHERICHIA coli, ELECTROLYTIC corrosion, CORROSION resistance, SURFACE topography, NANOCOATINGS, HYDROXYAPATITE coating

Abstract

To functionalize the NiTi alloy, multifunctional innovative nanocoatings of Ag-TiO2 and Ag-TiO2 doped with hydroxyapatite were engineered on its surface. The coatings were thoroughly characterized, focusing on surface topography and key functional properties, including adhesion, surface wettability, biocompatibility, antibacterial activity, and corrosion resistance. The electrochemical corrosion kinetics in a simulated body fluid and the mechanisms were analyzed. The coatings exhibited hydrophilic properties and were biocompatible with fibroblast and osteoblast cells while also demonstrating antibacterial activity against E. coli and S. epidermidis. The coatings adhered strongly to the NiTi substrate, with superior adhesion observed in the hydroxyapatite-doped layers. Conversely, the Ag-TiO2 layers showed enhanced corrosion resistance. [ABSTRACT FROM AUTHOR]

Published

2024

21. Study on Ni+W Combined with SiC Nanocoatings Prepared using Pulse Electrodeposition Method.

Author

Zhang, Yifeng, Xia, Fafeng, and Li, Huaxing

Subjects

ENERGY dispersive X-ray spectroscopy, ATOMIC force microscopy, HYDRAULIC cylinders, MILD steel, NANOCOATINGS

Abstract

Ni+W coating gained significant attention for designing metal parts, hydraulic cylinders, agricultural rods, and agricultural pumps because of their excellent resistance to wear and corrosion. In this study, Ni+W combined with SiC nanocoatings are successfully prepared on mild steel by utilizing the pulse electrodeposition strategy. The atomic force microscopy, scanning electron microscopy, x-ray diffractometer, energy dispersive x-Ray spectroscopy (EDX), friction wear test, and hardness tester were utilized to further investigate the surface morphology, phase structure, wear properties and hardness of Ni+W combined with SiC nanocoatings, respectively. The results indicated the ~ 32 nm SiC size in nanocoatings with a 6 g/L concentration of electrolyte. The Ni+W combined with SiC nanocoatings deposited at a SiC concentration of 6 g/L had a dense and smooth surface with a depression depth and a bump height of 76.3 nm and 106.6 nm, respectively. The result demonstrates that an uniform and smooth Ni+W combined with SiC nanocoating can be prefabricated by using appropriate plating parameters. The diffraction angles of 41.1, 51.9, and 71.1° correspond to the three diffraction peaks of the Ni+W combined with SiC nanocoatings fabricated at 3 g/L SiC concentration, which are the sharpest of all nanocoatings, corresponding to the (111), (200) and (220) planes of the Ni-W grains, respectively. Moreover, the minimum values of wear depth and wear width of Ni+W combined with SiC nanocoatings fabricated at a SiC concentration of 3 g/L were separately 33.1 μm and 5.6 mm. There are fine scratches and some shallowness on the surface of the Ni+W combined with SiC nanocoatings deposited at SiC concentration of 6 g/L, which indicates the outstanding tribological properties of the nanocoatings. Furthermore, there are Si, Ni, O and C elements present on the surface of the worn Ni+W combined with SiC nanocoatings observed by EDX results. [ABSTRACT FROM AUTHOR]

Published

2024

22. Effect of Corona Treatment Method to Carvacrol Nanocoating Process for Carvacrol/Halloysite-Nanotube/Low-Density-Polyethylene Active Packaging Films Development.

Author

Giannakas, Aris E., Karabagias, Vassilios K., Ndreka, Amarildo, Dimitrakou, Aikaterini, Leontiou, Areti A., Katerinopoulou, Katerina, Karakassides, Michael A., Proestos, Charalampos, and Salmas, Constantinos E.

Subjects

ACTIVE food packaging, CARVACROL, FOOD preservatives, LOW density polyethylene, NANOCOATINGS

Abstract

Active food packaging incorporated with natural plant extracts as food preservatives, which will totally replace chemical preservatives gradually, are of major interest. Sequentially to our and other scientists' previous work, in this paper we present the results of a study on the development of a novel active food packaging film based on the incorporation of a natural-halloysite/carvacrol-extract nanohybrid with the commercially used low-density polyethylene. The corona-treatment procedure was employed to incorporate a natural preservative on to the optimum final film. Packaging films are formatted with and without incorporation of natural-halloysite/carvacrol-extract nanohybrid and are coated externally, directly or via corona-treatment, with carvacrol essential oil. Mechanical, physicochemical, and preservation tests indicated that the low-density polyethylene incorporated perfectly with a natural-halloysite/carvacrol-extract nanohybrid. The extra external coating of the film with pure carvacrol extract using the corona-treatment technique led to approximately 100% higher Young Modulus values, slightly decreased ultimate strength by 20%, and exhibited almost stable elongation at break properties. The water vapor and oxygen properties were increased by 45 and 43%, correspondingly, compared to those of pure low-density polyethylene film. Finally, the antioxidant activity of the corona-treated film increased by 28% compared to the untreated film coated with carvacrol because of the controlled release rate of the carvacrol. [ABSTRACT FROM AUTHOR]

Published

2024

23. The Mechanical and Electrochemical Stability of Trimethysilane Plasma Nanocoatings Deposited onto Cobalt Chromium Cardiovascular Stents.

Author

Phan, ThiThuHa, Jones, John E., Liao, Yixuan, Yu, Qingsong, and Chen, Meng

Subjects

*HYDROPHILIC surfaces, *NANOCOATINGS, *SURGICAL stents, *CORROSION resistance, *SCANNING electron microscopy

Abstract

The objective of this study was to evaluate the coating integrity performance and corrosion protection property of trimethylsilane (TMS) plasma nanocoatings that were directly deposited onto cobalt chromium (CoCr) L605 cardiovascular stents. Hydrophilic surfaces were achieved for the TMS plasma nanocoatings that were deposited onto the coronary stents through NH3/O2 (2:1 molar ratio) plasma post-treatment. With a coating thickness of approximately 20–25 nm, the TMS plasma nanocoatings were highly durable and able to resist delamination and cracking from crimping and expansion by a Model CX with a J-Crimp Station. The stent surface that was evaluated by Scanning Electron Microscopy (SEM) and Energy-Dispersive X-ray Spectroscopy (EDS) showed no indications of pitting, corrosion, or adsorption products on either the luminal or abluminal surfaces of the stents, in contrast to the uncoated stent surface. The TMS plasma nanocoatings significantly enhanced the stent's corrosion resistance in immersion experiments that followed the ASTM F2129-15 corrosion protocol, evident in the increase of the open circuit potential (OCP) from 0.01 V for the uncoated L605 stent to 0.18 V for the plasma-nanocoated L605 stent, reducing potential cytotoxic metal ion release. Cyclic polarization (CP) curves show that the corrosion rate (density level) observed in plasma-nanocoated L605 stents was approximately half an order of magnitude lower than that of the uncoated stents, indicating improved corrosion protection of the stents. CP curves of the TMS plasma-nanocoated stents with different coating thicknesses show that, in the range of 20–65 nm, the coating thickness does not result in any difference in the corrosion resistance of the stents. [ABSTRACT FROM AUTHOR]

Published

2024

24. Trimethylsilane Plasma-Nanocoated Silver Nanowires for Improved Stability.

Author

Liao, Yixuan, Zhao, Ganggang, Ling, Yun, Yan, Zheng, and Yu, Qingsong

Subjects

*NANOCOATINGS, *HYDROPHILIC surfaces, *SUBSTRATES (Materials science), *ELECTRIC conductivity, *WEARABLE technology

Abstract

The objective of this study was to evaluate the effectiveness of trimethylsilane (TMS) plasma nanocoatings in protecting silver nanowires (AgNWs) from degradation and thus to improve their stability. TMS plasma nanocoatings at various thicknesses were deposited onto AgNWs that were prepared on three different substrates, including glass, porous styrene-ethylene-butadiene-styrene (SEBS), and poly-L-lactic acid (PLLA). The experimental results showed that the application of TMS plasma nanocoatings to AgNWs induced little increase, up to ~25%, in their electrical resistance but effectively protected them from degradation. Over a two-month storage period in summer (20–22 °C, 55–70% RH), the resistance of the coated AgNWs on SEBS increased by only ~90%, compared to a substantial increase of ~700% for the uncoated AgNWs. On glass, the resistance of the coated AgNWs increased by ~30%, versus ~190% for the uncoated ones. When stored in a 37 °C phosphate-buffered saline (PBS) solution for 2 months, the resistance of the coated AgNWs on glass increased by ~130%, while the uncoated AgNWs saw a ~970% rise. Increasing the TMS plasma nanocoating thickness further improved the conductivity stability of the AgNWs. The nanocoatings also transformed the AgNWs' surfaces from hydrophilic to hydrophobic without significantly affecting their optical transparency. These findings demonstrate the potential of TMS plasma nanocoatings in protecting AgNWs from environmental and aqueous degradation, preserving their electrical conductivity and suitability for use in transparent electrodes and wearable electronics. [ABSTRACT FROM AUTHOR]

Published

2024

25. Investigating the role of palladium electrical contacts in interactions with carbyne nanomaterial solid matter.

Author

Aleksandrova, Mariya

Subjects

PALLADIUM, THERMAL electrons, NANOSTRUCTURED materials, HYDROGEN isotopes, OHMIC contacts

Abstract

Introduction: Traps at the interface between carbyne and palladium nanocoatings, produced at different growth conditions, are explored by currentvoltage characteristics, scanning electron microscopy and thermal stimulation of charges for evaluation of their nature. It was found that the Pd films can form an Ohmic contact with the carbyne at certain deposition conditions and such deviated from the Ohmic behavior according to the RF sputtering voltage. This growth parameter was found to affect the interfacial traps formation on the carbyne surface, which is important feature for the charge trapping and releasing properties for hydrogen isotopes in the context of the energy release applications. Methods, Results and Discussion: The sputtering voltages of 0.5 kV and 0.7 kV were found unsuitable for controlled trap formation. Based on the currentvoltage and thermally stimulated current (TSC) measurements, a sputtering voltage of 0.9 kV appeared to be more favorable compared to 0.5 kV and 0.7 kV. At 0.9 kV thermal activation of charge carriers are enabled at lower thermal energies, showing a distinct change in TSC behavior correlated to trap activation. [ABSTRACT FROM AUTHOR]

Published

2024

26. Durable graphene-based alkyd nanocomposites for surface coating applications.

Author

Selim, Mohamed S., El-hoshoudy, Abdelaziz N., Zaki, ElSayed G., EL-Saeed, Ashraf M., and Farag, Ahmed A.

Subjects

SURFACE coatings, PROTECTIVE coatings, NANOCOMPOSITE materials, NANOCOATINGS, CHEMICAL properties

Abstract

Recently, the scientific community's main goal is the long-term sustainability. Vegetable oils are easily accessible, non-depletable, and cost-effective materials. Vegetable oils are used to prepare polymeric alkyd surfaces. Novel and exciting designs of alkyd/graphene nanocomposites have provided eco-friendly thermal stability and protective coating surfaces. This review has briefly described important graphene-based alkyd nanocomposites along with their applications as protective coatings. These alkyd composites have high hydrophobicity, corrosion resistance, and durability. Graphene-based alkyd nanocoatings have many industrial and research interests because of their exceptional thermal and chemical properties. This work introduces an advanced horizon for developing protective nanocomposite coatings. The anti-corrosion properties and coatings' longevity may be improved by combining the synergistic effects of hybrid nanofillers introduced in this work. [ABSTRACT FROM AUTHOR]

Published

2024

27. Role of Nanomaterials in Implant Dentistry

Author

Kawatra, Twinkle, Gupta, Deepshikha, Gupta, Tejendra K., Verma, Rohit, Garg, Seema, editor, Chandra, Amrish, editor, and Sagadevan, Suresh, editor

Published

2024

28. Optical and mechanical properties of aluminum oxide nanocoating prepared by pulse laser deposition.

Author

Hassan, Ayman M., Alwahib, Ali A., and Hussein, Abbas K.

Subjects

*PULSED laser deposition, *ALUMINUM oxide, *NANOCOATINGS, *OPTICAL properties, *YAG lasers, *ANTIREFLECTIVE coatings

Abstract

Aluminum oxide was deposited on the substrate using an Nd: YAG laser to prepare aluminum oxide nanocoating. The analysis tests showed that the nanocoating is polycrystalline and inhomogeneous distribution. The average surface roughness of the nanocoating increased from 1.33 nm to 3.7 nm with increased laser energy, and the number of pulses from 700 mJ and 100 pulses to 900 mJ and 300 pulses and a higher growth rate. UV-Visible Spectrophotometer was shown that sharp absorption in the ultraviolet (UV) region and high transmittance in the spectral region. The energy gap decreased from 4.1 eV to 4 even with the increased thickness of nanocoating from 56.4 nm to 176 nm. The nanocoating hardness test was carried out using the nanoindentation technique. The results showed that the hardness decreased from 33.83 GPa to 11.84 GPa with increased laser energy and a pulse from 700 mJ and 100 pulses to 900 mJ and 300 pulses due to internal defects caused by the increase in the thickness of the coating. [ABSTRACT FROM AUTHOR]

Published

2024

29. Effect of coupling agent type on the self-cleaning and anti-reflective behaviour of advance nanocoating for PV panels application.

Author

Mohammed, Taha Tareq, Judran, Hadia Kadhim, and Faraj, Sahar R.

Subjects

*COUPLING agents (Chemistry), *NANOCOATINGS, *CONTACT angle, *ELECTRIC power, *GLASS coatings

Abstract

The accumulation of soiling reduces the transformation of light radiation from the sun into electrical power, thus reducing the PV efficiency. Hence, so as to keep the performance steady, PV panels should be cleaned frequently. So, the self-cleaning procedure is the best technology and the coating method is one of these methods for PV panel surface cleaning. Novel superhydrophobic and superhydrophilic nanocoating were prepared with change the coupling agent by using a hybrid technique (sol-gel/ spray coating) with increased stability, optical transmittance, anti-soiling, anti-reflective, and minimize the corrosion effect. This nanocoating applies to the Photovoltaic solar panel to increase the electrical and optical performance of PV panels. The two coating settlements have been synthesized by using tetraethylorthosilicate (TEOS), Ethanol absolute, (APTES), and 3-(trimethoxysilyl) propyl methacrylate. These two solutions are coated on glass substrate by the air spray coating method. The chemical measurements of the nanocoating were tested by an (FE-SEM) field-emission scanning electron microscope. The results of the cross-section to SiO2 nanocoating about (1.8 µm) and the particle size were about (30 nm). The surface wettability was tested to identify the superhydrophobic and superhydrophilic by water contact angle (WCA) test, the degree values are 155˚ and 6.82˚ of superhydrophobic and hydrophilic coatings, respectively. The maximum value of transmittance was 94.949% at wavelength 884 nm. [ABSTRACT FROM AUTHOR]

Published

2024

30. Preparation and characterization of SiO2 nanocoating for self-cleaning solar panels.

Author

Mohammed, Taha Tareq, Judran, Hadia Kadhim, and Faraj, Sahar R.

Subjects

*SOLAR panels, *NANOCOATINGS, *CONTACT angle, *SCANNING electron microscopes, *SPRAYING & dusting in agriculture, *SUBSTRATES (Materials science), *PHOTOVOLTAIC power systems

Abstract

To improve the characteristic of self-cleaning, anti-dust, and electrical performance for photovoltaic (PV) panels, the traditional way of self-cleaning methods was impractical because it was expensive, scratches the glass of PV panels, corrosion, and may cause hazard to the environment which limited its application in the PV panels. Hence, the main object of this study was to create a novel super hydrophilic nanocoating by using a hybrid technique as (sol-gel/ spray coating). It produced more stability and reduce the corrosion, which would be very useful to apply in the solar cell panels. The coating solutions have been prepared by using Trimethoxysilane (3-Aminopropyl), Ethanol absolute and tetraethylorthosilicate (TEOS). The glass substrate was coated with different coating layers. XRD examinations proved that the material formed is pure silicon oxide (SiO2). The thickness, microstructure, and the particle size of the nanocoating were characterized by a field-emission scanning electron microscope (FE-SEM). The degree of super hydrophilicity was described by using the water contact angle (WCA) of a stagnant a very small drop of water on the coating measured with a contact angle meter. The spectra transmittance of the coated substrate was estimated by using a UV-spectrophotometer. The first sample, which was coated for one time, was the best among the other samples, because the optical transmittance was about 75%, and the water contact angle result was (6.92˚), this result shows the surface was superhydrophilic. [ABSTRACT FROM AUTHOR]

Published

2024

31. Effects of Nanocoating on the Performance of Photovoltaic Solar Panels in Al Seeb, Oman.

Author

Chala, Girma T., Sulaiman, Shaharin A., Chen, Xuecheng, and Al Shamsi, Salim S.

Subjects

*SOLAR panels, *NANOCOATINGS, *CLEAN energy, *SOLAR radiation, *ELECTRIC power production, *PHOTOVOLTAIC power generation, *PHOTOVOLTAIC power systems, *SOLAR power plants

Abstract

Solar photovoltaic (PV) panels are projected to become the largest contributor of clean electricity generation worldwide. Maintenance and cleaning strategies are crucial for optimizing solar PV operations, ensuring a satisfactory economic return of investment. Nanocoating may have potential for optimizing PV operations; however, there is insufficient scientific evidence that supports this idea. Therefore, this study aims to investigate the effectiveness of nanocoating on the performance of solar photovoltaic (PV) panels installed in Al Seeb, Oman. A further study was also carried out to observe the influence of coating layers on the performance of PV panels. One SiO2 nanocoated solar panel, another regularly cleaned PV panel, and a reference uncleaned panel were used to carry out the study. The site of the study was treeless and sandy, with a hot and dry climate. A data logger was connected to the solar PV panel and glass panel to record the resulting voltage, current, temperature, and solar radiation. It was observed that nanocoated PV panels outperformed both regular PV panels and uncleaned PV panels. Nanocoated PV panels demonstrated an average efficiency of 21.6%, showing a 31.7% improvement over uncleaned panels and a 9.6% improvement over regularly cleaned panels. Although nanocoating displayed high efficiency, regular cleaning also contributes positively. Furthermore, even though nanocoated PV panels outperformed the other two panels, it is important to note that the performance difference between the regular cleaned PV panels and the nanocoated PV panels was small. This indicates that regular cleaning strategies and nanocoating can further contribute to maintaining a more efficient solar PV system. Coating in many layers was also observed to influence the performance of PV panels insignificantly, mainly the fourth layer coating appeared to have formed sufficient mass to retain heat. [ABSTRACT FROM AUTHOR]

Published

2024

32. Microstructure, wear and corrosion resistances of Ni–ZrO2–CeO2 nanocoatings.

Author

Ma, Chunyang, Wang, Chen, Xia, Fafeng, Wang, Qi, Yan, Peng, and Zhang, Yifeng

Subjects

*NANOCOATINGS, *CORROSION resistance, *WEAR resistance, *CERIUM oxides, *MICROSTRUCTURE

Abstract

This study focused on the fabrication of Ni, Ni–ZrO 2 and Ni–ZrO 2 –CeO 2 nanocoatings using ultrasonic pulse electrodeposition. The research delved into examining the surface morphology, microhardness, abrasion, and corrosion resistance of these coatings. The results indicated that the Ni coatings displayed coarse grains and an irregular structure. Among the three, the Ni–ZrO 2 –CeO 2 nanocoatings exhibited the most dense, flat and fine microstructure among all three coatings, and the average diameters of Ni grains, ZrO 2 and CeO 2 nanoparticles were 68.6 nm, 21.1 nm and 23.4 nm, respectively. The Ni, Ni–ZrO 2 , and Ni–ZrO 2 –CeO 2 nanocoatings displayed high micro-hardness values, measuring an average of 363.1 Hv, 421.6 Hv, and 543.8 Hv, respectively. Moreover, the friction coefficient of Ni–ZrO 2 –CeO 2 nanocoatings was approximately 0.31. When exposed to a 3.5 wt% NaCl solution at room temperature, the Ni–ZrO 2 –CeO 2 nanocoatings displayed minimal corrosion damage, exhibiting the lowest corrosion rate of 0.06 mm/year compared to the other coatings. The incorporation of ZrO 2 and CeO 2 nanoparticles in the Ni–ZrO 2 –CeO 2 coating led to grain size reduction and a more uniform, compact microstructure, contributing to enhanced corrosion resistance when compared to both Ni and Ni–ZrO 2 coatings. [ABSTRACT FROM AUTHOR]

Published

2024

33. Preparation of organic–inorganic bio-based epoxy coatings with high anti-corrosive performance.

Author

Eral, Semiha, Oktay, Burcu, Dizman, Cemil, and Kayaman Apohan, Nilhan

Subjects

*EPOXY coatings, *NANOCOATINGS, *SOY oil, *EPOXY resins, *FOURIER transform infrared spectroscopy, *ETHYL silicate

Abstract

Epoxies derived from natural sources as an alternative to conventional petroleum-based epoxy resins have been used in sustainable coating applications. This study aims to create corrosion-resistant bio-based epoxy nanocoatings in the context of sustainable development. For this purpose, vegetable oil-based epoxy resins from cardanol and soybean oil were prepared. The structure of bio-based epoxies was confirmed by FTIR and 1H-NMR spectroscopy techniques. The epoxy functional silane precursor is synthesized from tetraethyl orthosilicate and (3-Glycidyloxypropyltrimethoxysilane by means of the sol–gel method. Amine curing agent and inorganic silica skeletons as polyhedral oligomeric silsesquioxanes and sol–gel precursor were added to the epoxy adduct and then cured. The curing kinetics of the formulations was followed by a differential scanning calorimeter. The chemical, mechanical, thermal, and anti-corrosive properties of the prepared coatings were investigated using various tests. The sustainable epoxy-based nanocoatings exhibited higher mechanical and thermal stability. In addition, the nanocoatings showed excellent corrosion resistance without the use of any anti-corrosive agent. The prepared green sustainable coatings will provide a more sustainable way to prepare bio-based coatings. [ABSTRACT FROM AUTHOR]

Published

2024

34. Solution‐Processed Nanocoating of Ca2Nb3O10 and Polydopamine for Anticorrosion on Magnesium Alloy.

Author

Yang, Kai, Zhang, Pengxiang, Feng, Zhenzhen, Wang, Yunfan, Peng, Jian, and Li, Bao‐Wen

Subjects

NANOCOATINGS, SALT spray testing, COMPOSITE coating, X-ray photoelectron spectroscopy, MAGNESIUM alloys, HEAT treatment

Abstract

2D materials have exhibited great potential for applications in anticorrosion nanocoatings. However, the nanocoating of prefocused graphene shows "corrosion‐promoting activity" due to its high conductivity. Metal oxide nanosheets obtained by delaminating layered oxides have been another attractive candidate. This study demonstrates a water‐based Ca2Nb3O10 (CNO) ink spray coated on magnesium alloys to form a continuous coating without complex functionalization and structural control. The composite coating of Ca2Nb3O10 (CNO) and polydopamine (PDA) is fabricated by combining spray‐ and dip‐coating methods. The surface composition and microstructure of the as‐prepared coatings are characterized by X‐ray diffractometry, Fourier transform infrared, X‐ray photoelectron spectroscopy, scanning electron microscopy, and energy‐dispersive spectrometry. The anticorrosion performance of the composite coating is evaluated by potentiodynamic polarization, electrochemical impedance spectroscopy, and salt spray tests. The electrochemical results show that the CNO/PDA heterostructure coating provides an enhanced corrosion inhibition efficiency (99.62%) with a corrosion current density of 5.49 × 10−7 A cm−2, three orders of magnitude lower than bare AZ31. The immersion tests before and after heat treatment and salt spray tests indicate that the composite coating has good stability and long‐term anticorrosion performance. Solution‐processed nanocoating and extensible materials design provide a green and facile route to anticorrosion nanotechnology for industrial demands. [ABSTRACT FROM AUTHOR]

Published

2024

35. Doping Engineering of Piezo‐Sonocatalytic Nanocoating Confer Dental Implants with Enhanced Antibacterial Performances and Osteogenic Activity.

Author

Pan, Qiyuan, Zheng, Yi, Zhou, Yang, Zhang, Xiao, Yuan, Meng, Guo, Jingying, Xu, Chao, Cheng, Ziyong, Kheraif, Abdulaziz A. Al, Liu, Min, and Lin, Jun

Subjects

*DENTAL implants, *NANOCOATINGS, *PIEZOELECTRICITY, *REACTIVE oxygen species, *ALVEOLAR process, *TITANATES, *STRONTIUM titanate

Abstract

Rescuing dental implants from plaque‐induced infection and implementing effective plaque control methods in a limited oral environment pose challenges for modern dentistry. To address this issue, Al ion doped strontium titanate/titanium dioxide nanotubes (Al‐SrTiO3/TiO2 nanotubes, Al‐STNT) are designed as an ultrasound‐responsive nanocoating immobilized on the Ti implant surface. Introducing Al3+ ions into the inorganic sonosensitive SrTiO3/TiO2 heterojunction induces oxygen vacancies and disrupts the lattice of SrTiO3. By overcoming the bandgap barrier through ultrasonic stimulated piezoelectric effect, Al‐STNT produces more reactive oxygen species (ROS). In the sonodynamic therapy (SDT) process, stimulus on Al‐STNT induces abundant ROS efficiently disrupting the bacteria biofilm and inhibiting biofilm metabolism. Moreover, the specific nanoscale SrTiO3 coating endows dental implants with osteogenic activity, facilitating the formation of rigid osseointegration between the implant surface and alveolar bone. By mimicking human dental implants in rats, Al‐STNT demonstrates optimal postimplant osseointegration while retaining its antibacterial ability as a sonosensitizer. Thanks to the portability of the ultrasound instrument and the stability of implant‐based sonosensitizer, this strategy presents an attractive option for patients to self‐treat and secure the long‐term success of their implants. [ABSTRACT FROM AUTHOR]

Published

2024

36. A Multifunctional Metal–Phenolic Nanocoating on Bone Implants for Enhanced Osseointegration via Early Immunomodulation.

Author

Liu, Jin, Shi, Yilin, Zhao, Yajun, Liu, Yue, Yang, Xiaoru, Li, Kai, Zhao, Weiwei, Han, Jianmin, Li, Jianhua, and Ge, Shaohua

Subjects

*OSSEOINTEGRATION, *NANOCOATINGS, *MESENCHYMAL stem cells, *IMMUNOREGULATION, *TANNINS, *BONE marrow, *TANTALUM, *STRONTIUM

Abstract

Surface modification is an important approach to improve osseointegration of the endosseous implants, however it is still desirable to develop a facile yet efficient coating strategy. Herein, a metal–phenolic network (MPN) is proposed as a multifunctional nanocoating on titanium (Ti) implants for enhanced osseointegration through early immunomodulation. With tannic acid (TA) and Sr2+ self‐assembled on Ti substrates, the MPN coatings provided a bioactive interface, which can facilitate the initial adhesion and recruitment of bone marrow mesenchymal stem cells (BMSCs) and polarize macrophage toward M2 phenotype. Furthermore, the TA‐Sr coatings accelerated the osteogenic differentiation of BMSCs. In vivo evaluations further confirmed the enhanced osseointegration of TA‐Sr modified implants via generating a favorable osteoimmune microenvironment. In general, these results suggest that TA‐Sr MPN nanocoating is a promising strategy for achieving better and faster osseointegration of bone implants, which can be easily utilized in future clinical applications. [ABSTRACT FROM AUTHOR]

Published

2024

37. Zirconia/bioactive glass composites development through a particle nanocoating.

Author

Soubelet, Clara G., Grillo, Claudia A., Suárez, Gustavo, and Stabile, Franco M.

Subjects

*GLASS composites, *BIOACTIVE glasses, *NANOCOATINGS, *ZIRCONIUM oxide, *DENTAL materials, *PARTICLE size distribution

Abstract

Zirconia based materials are widely used as dental materials because of their good mechanical properties and aesthetic, but there is a need of enhancing its biological response for clinical use. In that sense, a bioactive glass is added to zirconia matrix with the aim of improving the material biocompatibility. The effect of the raw powders synthesis method for dense zirconia/bioactive glass biomaterials was investigated. Two paths were developed to obtain zirconia-based composites with 2.5, 5 and 10 wt% addition of a bioactive glass (referred as 64S): the traditional powder mixture method, and a core-shell powder through sol-gel particle nanocoating. Particle size distribution and SEM images were performed for the powders characterization. Sol-gel coating was analyzed with TEM images and FT-IR spectra. The sintering process was studied with an optical dilatometer up to 1450 °C, and the density of the samples was calculated with the Archimedes method, in the range of 1100–1500 °C. The final crystalline phases were studied with Rietveld quantification through XRD analysis and the microstructure with SEM/EDS analysis. Vickers indentation method was used to evaluate the hardness. Biological properties were studied with murine fibroblast cell line L929 and were analyzed by fluorescence microscopy. Results showed that samples obtained by the sol-gel particle coating method enhanced the sintering process, with a sintering temperature in the range 1300–1400 °C; they showed a more homogeneous and pore-free microstructure with a higher retention of the t-ZrO 2 phase after cooling, in comparison with the samples obtained by the powder mixture method. The Vickers hardness of composites obtained by the core-shell particles had values above 11 GPa, and composites with 2.5 and 5 wt% 64S, sintered at 1400 °C, presented Vickers values of ∼13 GPa. Furthermore, biocompatibility was promoted with the addition of 64S glass, independently of the raw powders synthesis method. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

38. Effects of iron oxide nanocoatings on the seed germination, seedling growth, and antioxidant response of aromatic rice grown in the presence of different concentrations of rice straw extracts.

Author

Lin, Tingting, Chen, Xiying, Ren, Yong, Qing, Bowen, Zhang, Minghua, Mo, Zhaowen, and Wang, Shuli

Subjects

*GERMINATION, *FERRIC oxide, *AROMATIC plants, *RICE straw, *NANOCOATINGS, *IRON oxide nanoparticles, *SEEDLINGS

Abstract

Straw returning to the field has an inhibitory effect on seed germination and the early stage of seedling growth. Nanoparticles may contribute to good seed germination and seedling growth under stress. However, the effects of nanoparticles on seed germination and seedling growth of rice under straw returning remain unknown. Two popular aromatic rice varieties, Xiangyaxiangzhan and Meixiangzhan 2, were used as experimental materials. Three doses of iron oxide nanoparticles (Fe2O3 NPs) (i.e., 0 mg L−1, 25 mg L−1, and 50 mg L−1) were used for seed coating, and the nanoparticle-coated seeds were grown at three concentrations of straw extract (i.e., 0 g L−1, 10 g L−1, and 20 g L−1). The seed germination, seedling growth, antioxidant response, and nitrogen metabolism of aromatic rice were studied. The results showed that the aromatic rice varieties responded differently to straw concentration. Straw extract at 10 mg L−1 promoted the germination of Xiangyaxiangzhan but inhibited the germination of Meixiangzhan 2. With increasing straw extract concentration, the antioxidant response of Xiangyaxiangzhan increased. Fe2O3 NPs significantly increased seed germination under straw stress by 5–44%. The growth response of aromatic rice to iron oxide nanoparticle coating treatments varied among the different aromatic rice varieties and straw extract treatments. Therefore, iron oxide nanoparticle coating improved seed germination and regulated early growth and physiological parameters in aromatic rice. [ABSTRACT FROM AUTHOR]

Published

2024

39. Investigating the role of palladium electrical contacts in interactions with carbyne nanomaterial solid matter

Author

Mariya Aleksandrova

Subjects

carbyne, palladium electrodes, energy release, traps states, nanocoatings, Technology

Abstract

Introduction: Traps at the interface between carbyne and palladium nanocoatings, produced at different growth conditions, are explored by current-voltage characteristics, scanning electron microscopy and thermal stimulation of charges for evaluation of their nature. It was found that the Pd films can form an Ohmic contact with the carbyne at certain deposition conditions and such deviated from the Ohmic behavior according to the RF sputtering voltage. This growth parameter was found to affect the interfacial traps formation on the carbyne surface, which is important feature for the charge trapping and releasing properties for hydrogen isotopes in the context of the energy release applications.Methods, Results and Discussion: The sputtering voltages of 0.5 kV and 0.7 kV were found unsuitable for controlled trap formation. Based on the currentvoltage and thermally stimulated current (TSC) measurements, a sputtering voltage of 0.9 kV appeared to be more favorable compared to 0.5 kV and 0.7 kV. At 0.9 kV thermal activation of charge carriers are enabled at lower thermal energies, showing a distinct change in TSC behavior correlated to trap activation.

Published

2024

40. Superhydrophobic Nanocoatings on Galvanized Steel and Aluminum: Enhancing Oil & Gas Sustainability

Author

Maria Isabel Collasius Malta, Hugo Antonio Cavalcanti e Silva, Paulo Roberto Sá de Oliveira Neto, Rafael Gleymir Casanova da Silva, Walter Leandro Cordeiro da Silva Filho, Jedaías Januário da Silva, Severino Leopoldino Urtiga Filho, and Magda Rosângela Santos Vieira

Subjects

Nanocoatings, LDH films, Superoleophilicity, Superhydrophobicity, Water/oil Separation, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Superhydrophobic surfaces offer innovative solutions, particularly in water/oil separation systems, as they repel water and attract oil, enabling efficient separation. The study aimed to analyze coatings developed on galvanized steel and aluminum, regarding their wettability in saline water and diesel oil, aiming for applications in the oil and gas industry. Specimens underwent texturizing, in-situ growth of layered double hydroxide (ZnAl-LDH) film and modification with stearic acid (STA). Both LDH films exhibited similar binary hierarchical structures of hexagonal petals and micrometric flowers, interconnecting along the surface, forming pores that allowed for air entrapment after STA modification. CA for saline water exceeded 150º, and for diesel oil was under 10º, characterizing the coatings as superhydrophobic and superoleophilic. The coatings show promising potential for water/oil separation using recyclable substrates and a simple, low-cost, environmentally friendly process.

Published

2024

41. Effect of hipims discharge in metal oxide nanocoatings for resistive random access memory application.

Author

Różański, Piotr, Mroczyński, Robert, and Gajewski, Wojciech

Subjects

*NONVOLATILE random-access memory, *METALLIC oxides, *METAL nitrides, *TITANIUM nitride, *NANOCOATINGS

Abstract

This paper is devoted to the technology and characterization of thin films fabricated by reactive magnetron sputtering using HIPIMS discharge. The metal oxides and nitrides, such as zirconium oxide (ZrOx), titanium oxide (TiOx) or titanium nitride (TiN) play important functions in various structures for novel electronic and photonic devices. This work aims to determine dependencies between the input parameters of the fabrication process and the properties of the obtained materials to obtain ultrathin layers for the application of the MIM (Metal-Insulator-Metal) structures. Those structures are the basis of resistive random-access memory (RRAM) devices. In the first part of this work, the optical properties of layers deposited by HIPIMS were compared to those deposited using a typical pulsed-DC process. In the UV-VIS range, several oxide materials were characterized in terms of thickness, refractive indices, transmittance, and reflectance. The resistive switching properties of the MIM structures with the employed oxide materials depend on the presence of oxygen vacancies in the layer bulk. In order to monitor the stoichiometry of the oxide layers, MIS (Metal-Insulator-Semiconductor) structures are fabricated. The analysis of the obtained electrical characteristics was performed. In the last part of this work, selected processes were used to fabricate MIM devices. The results of the electrical characterization of the fabricated test structures will be described indicating concluding remarks on the feasibility of applying the studied structures in RRAM devices. [ABSTRACT FROM AUTHOR]

Published

2024

42. Thermal barrier coatings with nanostructured YSZ for high temperature application.

Author

Mehta, Amrinder, Vasudev, Hitesh, Singh, Sharanjit, Yedida, V. V. Satyavathi, and Singh, Rajesh

Subjects

*THERMAL barrier coatings, *THERMOMECHANICAL properties of metals, *HIGH temperatures, *NANOCOATINGS, *ELASTIC modulus

Abstract

The nanostructured YSZ coatings that Thermal Barrier Coatings (TBCs) applied to superalloy are going to be the primary topic of discussion throughout this review. There are a variety of methods available for measuring extrinsic mechanical attributes such as hardness, bond strength, and adhesion, in addition to intrinsic coating properties such as porosity and the condition of residual stress. According to the findings of the review, nanostructured coatings fared significantly better than conventional ones in terms of their resistance to oxidation. It's possible that the higher oxidation resistance of the nanocoating is due to the coating having a structure that is denser, more tightly packed, and more compact. The coating's thermomechanical properties were investigated by subjecting it to thermal cycles, thermal expansion, and elastic modulus testing; the results revealed that the nanostructured YSZ coating exhibited, once again, exceptional structural stability. According to the findings, the nanostructured YSZ has a lower level of thermal stress compared to the conventional YSZ. [ABSTRACT FROM AUTHOR]

Published

2024

43. Boron-based polyelectrolyte complex nanocoating for fire protection of engineered wood.

Author

Rodriguez-Melendez, Danixa, Vest, Natalie A., Kolibaba, Thomas J., Quan, Yufeng, Zhang, Zhuoran, Iverson, Ethan T., Wang, Qingsheng, and Grunlan, Jaime C.

Subjects

ENGINEERED wood, ORIENTED strand board, FIRE prevention, NANOCOATINGS, WOOD products, LUMBER

Abstract

Engineered wood products, such as oriented strand board (OSB), are widely used as the primary structural component in both residential and commercial lumber construction, primarily due to their renewability, aesthetic appeal, and excellent mechanical properties. Unfortunately, the inherent flammability of these wood-based composites poses an ongoing risk to society and the environment. In an effort to reduce its flammability, a polyelectrolyte complex (PEC) coating consisting of sodium polyborate (SPB) and polyethylenimine (PEI) was deposited on OSB using a simple two-dip process. This PEC treatment imparts self-extinguishing behavior to OSB and reduces the total heat release by 21% and total smoke release by 79%, while increasing the time to ignition by 18% relative to untreated OSB. Furthermore, the PEI/SPB coating adds little additional weight (5.8 wt%) to the oriented strand board, preserving visual aesthetics and maintaining mechanical properties. The main flame-retardant effect occurs by condensed phase action via a combination of intumescence and thermal barrier mechanisms. Improving the fire protection of OSB and other engineered wood materials through a simple and environmentally benign treatment will increase their potential as a largely renewable building material, promoting a sustainable bioeconomy. [ABSTRACT FROM AUTHOR]

Published

2024

44. Effect of Electrodeposition Method on the Abrasion Resistance of Ni-SiC Composite Nanocoatings.

Author

Liu, Haijun, Wang, Hui, and Guo, Xue

Subjects

MICROHARDNESS, ABRASION resistance, CELLULOSE nanocrystals, NANOCOATINGS, ELECTROPLATING, SCANNING electron microscopy, WEAR resistance

Abstract

This work reports the deposition of Ni-SiC composite nanocoatings (CNCs) on Q235 steel surface through different approaches, including direct current electrodeposition (DCE), pulse current electrodeposition (PCE), and ultrasonic-assisted pulse current electrodeposition (UPCE), respectively. The surface morphology, phase structure, SiC content, and microhardness of Ni-SiC CNCs were investigated via scanning electron microscopy, x-ray diffraction, energy dispersive spectroscopy, microhardness tester, and wear tester respectively. The results indicated that Ni-SiC CNCs fabricated via DCE acquired a porous structure, whereas those fabricated via UPCE exhibited a smooth surface. The diffraction angles of Ni grain were observed at 44.6°, 52.2°, and 78.3°, while the SiC exhibited the diffraction peak at 34.2°, 41.6°, and 59.7°. The UPCE approach yielded the highest SiC content and microhardness values for Ni-SiC CNCs, at 853.6 HV and 8.91 wt.%, respectively. Furthermore, the Ni-SiC CNCs deposited using the UPCE technique had depths of only 14.3 μm, demonstrating the best abrasion resistance. Ni-SiC CNCs produced with UPCE had a compact and fine microstructure with an excellent microhardness value, which effectively prevented surface damage. This study can provide a new method for preparing the nickel-based nanocoatings with excellent wear resistance. [ABSTRACT FROM AUTHOR]

Published

2024

45. Nanoencapsulation and Nanocoating of Bioactives of Application Interest in Food, Nutraceuticals and Pharma.

Author

Prieto, Cristina and Lagaron, Jose M.

Subjects

*NANOCOATINGS, *ACTIVE food packaging, *POLYCAPROLACTONE, *YOGURT, *SMALL-angle X-ray scattering, *WHEY protein concentrates, *TREHALOSE

Abstract

This article discusses the use of nanoencapsulation and nanocoating technologies to protect and enhance the functionality of bioactive compounds in the food, nutraceutical, and pharmaceutical sectors. The authors highlight the successful encapsulation of omega-3 rich oils and therapeutic proteins using these technologies, which improved stability and bioavailability. They also discuss the application of lipid nanometric systems in photoprotection and skin anti-aging, as well as the development of packaging materials with enhanced functionalities. Overall, the article emphasizes the transformative potential of nanotechnology in improving bioactive formulations and calls for further interdisciplinary research in this field. [Extracted from the article]

Published

2024

46. Polydopamine nanocoating on cellulose nanofiber film and its multifunctional behaviors.

Author

Muthoka, Ruth M., Panicker, Pooja S., Agumba, Dickens O., and Kim, Jaehwan

Subjects

NANOCOATINGS, CELLULOSE, ATOMIC force microscopy, YOUNG'S modulus, VITAMIN C

Abstract

This paper presents a simple and upscalable method for enhancing and imparting multifunctionalities onto cellulose nanofiber (CNF) films through nanocoating with polydopamine (PDA). Leveraging a simple two-step process of dopamine seeding and PDA polymerization in mild alkaline Tris–HCl, a uniform and stable PDA nanocoating was successfully formed on the CNF film surface. The resulting PDA-coated CNF films (PDA–CNF) were then thermally annealed at 160 °C to further enhance their multifunctionality. Our results show that the PDA nanocoating profoundly enhanced the films' UV-shielding properties, Young's modulus, dielectric properties, and antioxidant activity. FTIR spectra analysis confirmed successful PDA formation onto the CNF surface, and atomic force microscopy revealed a homogenous distribution of nanometer-sized PDA oligomers (~ 170 nm) on the film surface. Moreover, we demonstrated the use of thermally annealed PDA–CNF film as an ascorbic acid detecting electrode, which showed a linear electrochemical response with high stability and excellent reproducibility. These findings contribute to the expanding knowledge of CNF films and their potential as a promising material for various applications. [ABSTRACT FROM AUTHOR]

Published

2024

47. Investigation of smart graphene oxide multilayer nanocoating for improved steel structural protection in natural seawater.

Author

Beryl, J. Raja and Xavier, Joseph Raj

Subjects

*STRUCTURAL steel, *GRAPHENE oxide, *HEAT release rates, *NANOCOATINGS, *SEAWATER, *FIRE resistant polymers, *ARTIFICIAL seawater

Abstract

The GO-AMTT/TiS2 nanofiller was developed by combining surface-modified titanium disulphide (TiS2) with graphene oxide (GO) and 2-amino-5-methylthio-1H-1,2,4-triazole (AMTT), and it was subsequently incorporated into the epoxy resin (EP) to produce EP-GO-AMTT/TiS2 nanocomposite. Using electrochemical impedance spectroscopy (EIS) and scanning electrochemical microscopy (SECM), the performance of epoxy coating on mild steel as a barrier against different concentrations of GO-AMTT/TiS2 in naturally occurring seawater was evaluated. It was found that that epoxy coating with 0.6 weight percent of GO-AMTT/TiS2 nanoparticles exhibited the highest resistance after exposed to seawater for 1 h. The limiting oxygen index test and thermogravimetric analysis revealed that the GO/AMTT-TiS2 significantly improved the flame retardancy properties of the epoxy coating. The peak heat release rate and total heat release values for the EP-GO/AMTT-TiS2 significantly decreased by 74% and 66%, respectively, as compared to pure EP, showing that the material is more flame retardant. The EIS experiments showed that the EP-GO/AMTT-TiS2 nanocomposite had increased coating resilience even after 960 h of submersion in seawater. According to SECM investigations, a small amount of ferrous ions was released at the scribe area of the EP-GO/AMTT-TiS2 coating. This is because the coated substrate is more resistant to anodic dissipation than the uncoated substrate. The developed EP-GO/AMTT-TiS2 coating has higher protective and hydrophobic (WCA: 157°) characteristics. The epoxy matrix's adhesive properties were enhanced by the addition of GO/AMTT-TiS2. Therefore, an EP-GO/AMTT-TiS2 nanocomposite may be employed in an industrial coating. [ABSTRACT FROM AUTHOR]

Published

2024

48. Effectiveness of Coatings in Reducing biofilm Adhesion on Arch Wires.

Author

Chaudhari, Rhujuta, Ravindranath, V. K., Gheware, Anjali, Mhatre, Amol, and Jain, Anchal

Subjects

*BACTERIAL adhesion, *PATIENT compliance, *NANOCOATINGS, *NANOPARTICLES, *RISK assessment

Abstract

Effectiveness of coatings in reducing biofilm adhesion on archwire was evaluated. Literature search was conducted on PubMed, Medline, Google Scholar, and Science Direct which analysed the anti-adherent property after nanocoating of archwires against uncoated group. Two risk of bias assessment tools were used and the data extracted from each study was then tabulated. Eight studies fulfilled the inclusion criteria. Risk of bias assessment showed a low - moderate risk for most of included studies. Various nanoparticle coatings were analysed for their antimicrobial property. Adequate implementation of each type of coated arch-wire can aid in reducing the bacterial aggregation around the orthodontic attachments and keeping the white spot lesions at bay irrespective of patient compliance. Most of the studies included in this systematic review were assessed fair in risk of bias assessment. Due to presence of heterogenicity in terms of varied coating methods employed to check the antimicrobial property, a meta-analysis was not possible. [ABSTRACT FROM AUTHOR]

Published

2024

49. HEAT DISSIPATION EFFECTS OF DIFFERENT NANOCOATED LATERAL FINS An Experimantal Investigation.

Author

MANI, Premkumar, RADHAKRISHNAN, Santhanakrishnan, MAHALINGAM, Arulprakasajothi, and VELLAIYAN, Suresh

Abstract

Electrical batteries, mobile phones, central processing units of computing systems, and scientific instruments lose life due to improper heat transfer. Thermal management enables these electronics to run smoothly. This experiment measures heat sink temperature fluctuations during heating and cooling using lateral fins coated with graphene and carbon CNT. The study examined 15 W, 25 W, 35 W, and 45 W heat inputs to record the time to reach 40 °C, 50 °C, and 60 °C. Regardless of the coating material used in the heat sink, the time taken by the heat sinks to attain 60 °C was more than 3000 seconds. Heat input reduced the time to below 3000 seconds. Heat sinks dissipated heat until 32 °C during cooling. Infrared spectroscopy showed fins and heat sinks’ energy retention. Convective heat transfer cooled the middle row of fins, and coated and uncoated heat sinks were evaluated for enhancement ratio. Coating the heat sink with graphene resulted in an enhancement in heat transfer by 1.15. While heating at 15 W, the CNT coated heat sink exhibited a 1.9 enhancement ratio. The graphene-coated heat sink had an enhancement ratio for 25 W, 35 W, and 45 W heat inputs. The study found that operating temperature, input energy, and nanocoatings affect heat sink performance. This work can help optimise heat transfer from the heat sink to the atmosphere by determining nanocoating thickness. Mixed-material coating studies can disclose heat sink performance. [ABSTRACT FROM AUTHOR]

Published

2024

50. Organic-inorganic composite nanocoatings with superhydrophobicity and thermal stability.

Author

Syafiq, A., Pandey, A.K., Balakrishnan, Vengadaesvaran, Shahabuddin, Syed, and Rahim, Nasrudin Abd

Subjects

*THERMAL stability, *NANOCOATINGS, *CONTACT angle, *SUPERHYDROPHOBIC surfaces, *TEMPERATURE control, *SURFACE roughness, *SUPERPARAMAGNETIC materials

Abstract

Purpose: This paper aims to investigate the thermal stability and hydrophobicity of difference alkyl chain of silanes with silicon (Si) micro- and nanoparticles. Design/methodology/approach: Sol-gel methods have been used to design superhydrophobic glass substrates through surface modification by using low-surface-energy Isooctyl trimethoxysilane (ITMS) and Ethyl trimethoxysilane (ETMS) solution. Hierarchical double-rough scale solid surface was built by Si micro- and nanoparticles to enhance the surface roughness. The prepared sol was applied onto glass substrate using dip-coating method and was dried at control temperature of 400°C inside the tube furnace. Findings: The glass substrate achieved the water contact angle as high as 154 ± 2° and 150.4 ± 2° for Si/ITMS and Si/ETMS films, respectively. The Si/ITMS and Si/ETMS also were equipped with low sliding angle as low as 3° and 5°, respectively. The Si micro- and nanoparticles in the coating system have created nanopillars between them, which will suspend the water droplets. Both superhydrophobic coatings have showed good stability against high temperature up to 200°C as there are no changes in WCA shown by both coatings. Si/ITMS film sustains its superhydrophobicity after impacting with further temperature up to 400°C and turns hydrophobic state at 450°C. Research limitations/implications: Findings will be useful to develop superhydrophobic coatings with high thermal stability. Practical implications: Sol method provides a suitable medium for the combination of organic-inorganic network to achieve high hydrophobicity with optimum surface roughness. Originality/value: Application of different alkyl chain groups of silane resin blending with micro- and nanoparticles of Si pigments develops superhydrophobic coatings with high thermal stability. [ABSTRACT FROM AUTHOR]

Published

2024