UPSI Digital Repository (UDRep)
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UPSI Digital Repository (UDRep)
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| Abstract : Universiti Pendidikan Sultan Idris |
| Recent progress in using copper oxide (CuO) nanomaterials to prepare superhydrophobic properties has encouraged significant advancements across various applications. This comprehensive review examines and consolidates the latest progress in CuO nanostructure synthesis and its applications in fabricating superhydrophobic surfaces. The review includes a multifaceted investigation, beginning with an analysis of the synthesis methods, followed by a study of natural superhydrophobic surfaces, drawing inspiration from their innate properties to prepare artificial equivalents. It proceeds to explore recent advancements in creating and employing CuO superhydrophobic surfaces and the inherent factors impacting their preparation. A crucial aspect involves characterizing the wetting properties of CuO superhydrophobic layers, unveiling the mechanisms governing their functionality across surfaces. Highlighting the essential role of CuO superhydrophobic surfaces, this review emphasizes their significance in various industry applications. However, it also confronts the inherent challenges and limitations in harnessing CuO nanostructure to prepare effective superhydrophobic surfaces, paving the way for future research directions. This comprehensive review fills a critical void in current knowledge and guides the evolution and application of CuO superhydrophobic surfaces in diverse domains. © The Author(s), under exclusive licence to Springer Science+Business Media, LLC, part of Springer Nature 2024. |
| References |
Tran TH, Nguyen VT (2014) Copper oxide nanomaterials prepared by solution methods, some properties, and potential applications: a brief review. Int Sch Res Not 2014:856872. Reddy RCK, Lin J, Chen Y, Zeng C, Lin X, Cai Y, Su C-Y (2020) Progress of nanostructured metal oxides derived from metal–organic frameworks as anode materials for lithium–ion batteries. Coord Chem Rev 420:213434. Ou LX, Liu MY, Zhu LY, Zhang DW, Lu HL (2022) Recent progress on fexible room-temperature gas sensors based on metal oxide semiconductor. Nano-Micro Lett 14(1):206. Divakaran AM, Mondal K (2022) Metal oxide nanostructures for gas sensing applications. In: Gas Sensors, CRC Press, pp 261–270. Das C, Sinha N, Roy P (2022) Transition Metal Non-Oxides as Electrocatalysts: Advantages and Challenges. Small 18(28):2202033. Lamiel C, Hussain I, Rabiee H, Ogunsakin OR, Zhang K (2023) Metal-organic framework-derived transition metal chalcogenides (S, Se, and Te): Challenges, recent progress, and future directions in electrochemical energy storage and conversion systems. Coord Chem Rev 480:215030. Qumar U, Hassan JZ, Bhatti RA, Raza A, Nazir G, Nabgan W, Ikram M (2022) Photocatalysis vs adsorption by metal oxide nanoparticles. J Mater Sci Technol 131:122–166. https://doi.org/10.1016/j.jmst.2022.05.020. Chang C-J, Lai C-W, Jiang W-C, Li Y-S, Choi C, Yu H-C, Chen S-J, Choi Y (2022) Fabrication and characterization of P-type semiconducting copper oxide-based thin-flm photoelectrodes for solar water splitting. Coatings 12(8):1206. Baral SC, Maneesha P, Sen S, Sen S, Sen S (2023) An introduction to metal oxides. In: Optical properties of metal oxide nanostructures, Springer, pp 1–34. Okoye P, Azi S, Qahtan T, Owolabi T, Saleh T (2023) Synthesis, properties, and applications of doped and undoped CuO and Cu2O nanomaterials. Mater Today Chem 30:101513. Bhosale SR, Ghatage SA, Wahane PN, Bhosale RR, Jagadhane KS, Patil DN, Anbhule PV (2022) Formation of CuO nanostructures via chemical route for biomedical applications. Chem Phys Lett 808:140122. Kabir MH, Ibrahim H, Ayon SA, Billah MM, Neaz S (2022) Structural, nonlinear optical and antimicrobial properties of solgel derived, Fe-doped CuO thin flms. Heliyon 8(9):e10609. Omar NMA, Othman MHD, Tai ZS, Amhamed AOA, Yuliwati E, Puteh MH, Kurniawan TA, Rahman MA, Jaafar J, Ismail AF (2023) Robust omniphobic ceramic hollow fbre membrane with leaf-like copper oxide hierarchical structure by membrane distillation. Desalination 564:116816. Sibhatu AK, Weldegebrieal GK, Imteyaz S, Sagadevan S, Tran NN, Hessel V (2022) Synthesis and process parametric efects on the photocatalyst efciency of CuO nanostructures for decontamination of toxic heavy metal ions. Chem Eng Process-Process Intensif 173:108814. Ayyasamy LR, Mohan A, Rex LK, Sivakumar VL, Dhanasingh SV, Sivasamy P (2022) Enhanced thermal characteristics of CuO embedded lauric acid phase change material. Therm Sci 26(2):1615–1621. Madvar HR, Kordrostami Z, Mirzaei A (2022) Sensitivity enhancement of resistive ethanol gas sensor by optimized sputtered-assisted CuO decoration of ZnO nanorods. Sensors 23(1):365. Wang N, Tao W, Gong X, Zhao L, Wang T, Zhao L, Liu F, Liu X, Sun P, Lu G (2022) Highly sensitive and selective NO2 gas sensor fabricated from Cu2O-CuO microfowers. Sens Actuators, B Chem 362:131803. Han D, Lougou BG, Shuai Y, Wang W, Jiang B, Shagdar E (2022) Study of thermophysical properties of chloride salts doped with CuO nanoparticles for solar thermal energy storage. Sol Energy Mater Sol Cells 234:111432. Mallakpour S, Azadi E, Hussain CM (2020) Environmentally benign production of cupric oxide nanoparticles and various utilizations of their polymeric hybrids in diferent technologies. Coord Chem Rev 419:213378. Zhao J, Liu Z, Low SC, Xu Z, Tan SH (2023) Biomimetic hydrophilic CuO-nanocluster/nanofbrous thin-flm skeleton/ hydrophilic CuO-nanocluster architecture membrane for efcient and stable solar water evaporation. J Alloys Compd 969:172377. Lu R, Yu Y, Adkhamjon G, Gong W, Sun X, Liu L (2020) Bio-inspired cotton fabric with superhydrophobicity for highefciency self-cleaning and oil/water separation. Cellulose 27:7283–7296. Zhang Q, Zhang K, Xu D, Yang G, Huang H, Nie F, Liu C, Yang S (2014) CuO nanostructures: synthesis, characterization, growth mechanisms, fundamental properties, and applications. Prog Mater Sci 60:208–337. Lv Z, Yu S, Song K, Zhou X, Yin X (2020) Fabrication of a leaf-like superhydrophobic CuO coating on 6061Al with good self-cleaning, mechanical and chemical stability. Ceram Int 46(10):14872–14883. Omar NMA, Othman MHD, Tai ZS, Rabuni MF, Amhamed AOA, Puteh MH, Jaafar J, Rahman MA, Kurniawan TA (2024) Overcoming challenges in water purifcation by nanocomposite ceramic membranes: a review of limitations and technical solutions. J Water Process Eng 57:104613. Cao C, Wang F, Lu M (2020) Superhydrophobic CuO coating fabricated on cotton fabric for oil/water separation and photocatalytic degradation. Colloids Surf, A 601:125033. Omar NMA, Othman MHD, Tai ZS, Amhamed AOA, Kurniawan TA, Puteh MH, Sokri MNM (2023) Recent progress, bottlenecks, improvement strategies and the way forward of membrane distillation technology for arsenic removal from water: a review. J Water Process Eng 52:103504. Bouafa A, Laouini SE, Ouahrani MR (2020) A review on green synthesis of CuO nanoparticles using plant extract and evaluation of antimicrobial activity. Asian J Res Chem 13(1):65–70. Wang S, Fan B, Lv C, Jia X, Wang T (2020) Infuence of adhesives on the construction of a robust superamphiphobic surface. J Alloy Compd 831:154741. |
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