Ảnh hưởng của nồng độ Ce3+ lên cấu trúc và tính chất quang của vật liệu nano ZnO chế tạo bằng phương pháp sol-gel

Chỉ số đề mục

Lĩnh vực nghiên cứu

Khoa học kỹ thuật và công nghệ

Dạng tài liệu

BB

Tác giả

Đặng Thị Bích Hợp*, Nguyễn Văn Cường, Hoàng Quốc Thuận , Lê Tiến Hà⁽¹⁾, Nguyễn Văn Quang, Nguyễn Văn Cường, Phạm Thị Lan Hương⁽³⁾⁽²⁾

Nhan đề

Ảnh hưởng của nồng độ Ce3+ lên cấu trúc và tính chất quang của vật liệu nano ZnO chế tạo bằng phương pháp sol-gel

Nhan đề tiếng anh

Effect of the Ce3+ concentration on the crystallite structure and optical properties of ZnO nanomaterials synthesised by sol-gel method

Nguồn trích

Tạp chí Khoa học và Công nghệ Việt Nam - B

Năm xuất bản

2023

Số

11B

Trang

63

ISSN

Từ khóa

Từ khóa tiếng anh

Tóm tắt

Trong nghiên cứu này, vật liệu nano ZnO pha tạp Ce3+ (Zn1-xO:xCe3+) được chế tạo thành công bằng phương pháp sol-gel. Kết quả phân tích giản đồ nhiễu xạ tia X (XRD) và phổ Raman cho thấy, ở nồng độ pha tạp 1%, ion Ce3+ đã thay thế cho ion Zn2+...

Tóm tắt tiếng anh

In this study, Ce3+-doped ZnO nanomaterials (Zn1-xO:xCe3+ NPs) were synthesised using the sol-gel method. X-ray diffraction (XRD) pattern and Raman spectra analysis showed that at 1% doping concentration, Zn2+ ions were replaced with Ce3+ ions in the ZnO lattice...

Kí hiệu kho

File toàn văn

Xem toàn văn

Tài liệu tham khảo

[1] Y.I. Jung, B.Y. Noh, Y.S. Lee, et al. (2012), Visible emission f-rom Ce-doped ZnO nanorods grown by hydrothermal method without a post thermal annealing process,Nanoscale Research Letters
[2] D.Q. Trung, N.V. Quang, M.T. Tran, et al. (2021), Single-composition Al³⁺-singly doped ZnO phosphors for UV-pumped warm white light-emitting diode applications,Dalton Transactions
[3] J.O. Primo, C. Bittencourt, S. Acosta, et al. (2020), Synthesis of zinc oxide nanoparticles by ecofriendly routes: Adsorbent for copper removal f-rom wastewater,Frontiers in Chemistry
[4] B. Chouchene, T.B. Chaabane, L. Balan, et al. (2016), High performance Ce-doped ZnO nanorods for sunlight-driven photocatalysis,Beilstein Journal of Nanotechnology
[5] M. Wang, F. Ren, J. Zhou, et al. (2015), N doping to ZnO nanorods for photoelectrochemical water splitting under visible light: Engineered impurity distribution and terraced band structure,Scientific Reports
[6] D.N. Montenegro, V. Hortelano, O. Mart (2013), Non-radiative recombination centres in catalyst-free ZnO nanorods grown by atmospheric-metal organic chemical,Journal of Physics D: Applied Physics
[7] J. Yang, M. Gao, L. Yang, et al. (2008), Low-temperature growth and optical properties of Ce-doped ZnO nanorods,Applied Surface Science
[8] M.L.A. Letswalo, L. Reddy, A. Balakrishna, et al. (2021), The role of sulfate ions on distinctive defect emissions in ZnO:Ce³⁺ nanophosphors – A study on the application in color display systems,Journal of Luminescence
[9] L. Wang, Z. Ji, J. Lin, et al. (2017), Preparation and optical and photocatalytic properties of Ce-doped ZnO microstructures by simple solution method,Materials Science in Semiconductor Processing
[10] T.K. Pathak, E.C. Hugo, H.C. Swart, et al. (2020), Preparation and c-haracterization of Ce doped ZnO nanomaterial for photocatalytic and biological applications,Materials Science and Engineering B
[11] G.L. Tan, D. Tang, D. Dastan, et al. (2021), Effect of heat treatment on electrical and surface properties of tungsten oxide thin films grown by HFCVD technique,Materials Science in Semiconductor Processing
[12] D. Anbuselvan, S. Muthukumaran (2015), Defect related microstructure, optical and photoluminescence behaviour of Ni, Cu co-doped ZnO nanoparticles by co-precipitation method,Optical Materials
[13] M. Faisal, A.A. Ismail, A.A. Ibrahim (2013), Highly efficient photocatalyst based on Ce doped ZnO nanorods: Controllable synthesis and enhanced photocatalytic activity,Chemical Engineering Journal
[14] N. Tu, H.V. Bui, D.Q. Trung (2019), Surface oxygen vacancies of ZnO: A facile fabrication method and their contribution to the photoluminescence,Journal of Alloys and Compounds
[15] Sukriti, P. Chand, V. Singh, et al. (2020), Rapid visible light-driven photocatalytic degradation using Ce-doped ZnO nanocatalysts,Vacuum
[16] M. Shatnawi, A.M. Alsmadi, I. Bsoul, et al. (2016), Magnetic and optical properties of Co-doped ZnO nanocrystalline particles,Journal of Alloys and Compounds
[17] N.K. Singh, V. Koutu, M.M. Malik (2019), Enhancement of room temperature ferromagnetic behavior of Co-doped ZnO nanoparticles synthesized via sol-gel technique,Journal of Sol-Gel Science and Technology
[18] S. Rajendran, M.M. Khan, F. Gracia, et al. (2016), Ce³⁺-ion-induced visible-light photocatalytic degradation and electrochemical activity of ZnO/CeO₂ nanocomposite,Scientific Reports
[19] J.C.G. Crisostomo, R.L. Juárez, V. Petranovskii (2021), Photocatalytic degradation of rhodamine B dye in aqueous suspension by ZnO and M-ZnO (M=La³⁺, Ce³⁺, Pr³⁺ and Nd³⁺) nanoparticles in the presence of UV/H₂O₂,Processes
[20] S. Kalpana, S.S. Krishnan, A. Bhaskaran (2018), Effect of chromium doping on structural, optical and photocatalytic properties of ZnO nanoparticles,Advanced Materials Rapid Communications
[21] P.T.L. Huong, N.V. Quang, D.Q. Trung, et al. (2022), Excellent visible light photocatalytic degradation and mechanism insight of Co²⁺‑doped ZnO nanoparticles,Applied Physics A
[22] L. Kumaresan, A. Prabhu, M. Palanichamy, et al. (2011), Synthesis and c-haracterization of Zr⁴⁺, La³⁺ and Ce³⁺ doped mesoporous TiO₂: Evaluation of their photocatalytic activity,Journal of Hazardous Materials
[23] M.K. Hussen, F.B. Dejene, M. Tsega (2019), Effect of pH on material properties of ZnAl₂O₄:Cr³⁺ nanoparticles prepared by sol–gel method,Journal of Materials Science: Materials in Electronics
[24] N.X. Sang, N.M. Quan, N.H. Tho, et al. (2019), Mechanism of enhanced photocatalytic activity of Cr-doped ZnO nanoparticles revealed by photoluminescence emission and electron spin resonance,Semiconductor Science and Technology
[25] S. Stojadinovi, R. Vasili, N. Radic (2020), Enhanced ultraviolet light driven photocatalytic activity of ZnO particles incorporated by plasma electrolytic oxidation into Al₂O₃ coatings co-doped with Ce³⁺,Optical Materials
[26] Y. Liu, L. Yu, et al. (2012), A magnetically separable photocatalyst based on nest-like γ-Fe₂O₃/ZnO double-shelled hollow structures with enhanced photocatalytic activity,Nanoscale
[27] S.K. Yadav, P. Jeevanandam (2016), Synthesis of ZnO@γ-Fe₂O₃ core–shell nanocomposites by a facile thermal decomposition approach and their application in photocatalytic degradation of Congo red,Journal of Nanoparticle Research
[28] S. Kuriakose, B. Satpati, S. Mohapatra (2014), Enhanced photocatalytic activity of Co doped ZnO nanodisks and nanorods prepared by a facile wet chemical method,Physical Chemistry Chemical Physics
[29] C.B. Ong, L.Y. Ng, A.W. Mohammad (2018), A review of ZnO nanoparticles as solar photocatalysts: Synthesis, mechanisms and applications,Renewable and Sustainable Energy Reviews
[30] G. Thennarasu, A. Sivasamy (2018), Mn doped ZnO nanomaterial: A highly visible light active photocatalyst for environmental abatement,Inorganic and Nano-Metal Chemistry
[31] R. Ebrahimi, K. Hossienzadeh, A. Maleki, et al. (2019), Effects of doping zinc oxide nanoparticles with transition metals (Ag, Cu, Mn) on photocatalytic degradation of direct blue 15 dye under UV and visible light irradiation,Journal of Environmental Health Science and Engineering
[32] K. Dib, M. Trari, Y. Bessekhouad (2019), (S,C) co-doped ZnO properties and enhanced photocatalytic activity,Applied Surface Science
[33] U. Godavarti, V.D. Mote, M.V.R. Reddy, et al. (2019), Precipitated cobalt doped ZnO nanoparticles with enhanced low temperature xylene sensing properties,Physica B: Condensed Matter