A green, simple, and cost-effective synthesis for copper nanoparticles has been investigated using ascorbic acid as a reductant and Citrus grandis peel extract as a stabilizer by microwave irradiation. In this method, using the pectin-enriched extract of Citrus grandis peel as a stabilizer for forming copper nanoparticles was potentially a new path for efficiently utilizing by-products. The effect of precursor, reductant, and stabilizer on the formation of copper nanoparticles by microwave irradiation and conventional heating was investigated. The obtained results indicated that copper nanoparticles were formed with a high-pure phase at an absorption maximum of 608 nm. Pectin-stabilized copper nanoparticles have a spherical shape with an average diameter of copper nanoparticles by conventional heating at approximately 9 nm and copper nanoparticles irradiated by microwave around 14 nm. The synthesized materials exhibited effective activity toward fungi with the IC50 value of 2.59 and 3.28 pM for conventional heating and 3.03 and 2.69 pM for microwave irradiation against Fusarium solani and Colletotrichum gloeosporioides, respectively. Although the particle size and antifungal efficiency of copper nanoparticles synthesized by microwave irradiation and conventional heating seem similar, the shortened reduction, high-purity product, and high synthesis efficiency were considered outstanding advantages of microwave irradiation. Therefore, the synthesized copper nanoparticles using the mixture of extract of Citrus grandis peel and ascorbic acid under microwave irradiation was proposed as a promising method with eco-friendly and effective antifungal properties that can replace pesticides in crop production.
Trung, N.D., Loc, L.C. and Tri, N., 2017. Determination of coke on promoted zirconium oxide catalysts in the isomerization re-action of pentane and hexane mixture at high pressure. Can Tho University Journal of Science. 7: 13-18.
Trung, N.D., Nhuan, N.T., Hieu, M.V. and Hong, N.T., 2020. Al2TiO5/SBA-15 promoting photocatalytic degradation of cinnamic acid. Can Tho University Journal of Science. 12(2): 45-52.
Tạp chí khoa học Trường Đại học Cần Thơ
Lầu 4, Nhà Điều Hành, Khu II, đường 3/2, P. Xuân Khánh, Q. Ninh Kiều, TP. Cần Thơ
Điện thoại: (0292) 3 872 157; Email: tapchidhct@ctu.edu.vn
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