Research progress of p-type cuprous oxide in the field of light energy utilization
Analysis of the application of cuprous oxide, as a typical p-type inorganic semiconductor material, widely used in the field of optical energy, photoelectrics, photocatalysis, photodegradation and as nanomaterials to improve the performance of solar cells
| Рубрика | Физика и энергетика |
| Вид | статья |
| Язык | английский |
| Дата добавления | 14.12.2024 |
| Размер файла | 1,6 M |
Отправить свою хорошую работу в базу знаний просто. Используйте форму, расположенную ниже
Студенты, аспиранты, молодые ученые, использующие базу знаний в своей учебе и работе, будут вам очень благодарны.
8. Zuo C, Ding L. Solution-Processed Cu2O and CuO as Hole Transport Materials for Efficient Perovskite Solar Cells. Small 2015; 11:5528-5532.
9. Zhang L., Sun H., Xie L., Lu J., Zhang L., Wu S., Liu J. M. Inorganic solar cells based on electrospun ZnO nanofibrous networks and electrodeposited Cu2O // Nanoscale research letters. - 2015. V. 10. №1. P. 1-13.
10. Koo H.S., Wang D.T., Yu YK., Ho S.H., Jhang J.Y., Chen M., Tai M.F. Effect of Cu2O Doping in TiO2 Films on Device Performance of Dye-Sensitized Solar Cells // Japanese Journal of Applied Physics. 2012. V. 51. №10S. P 10NE18.
11. Miao X., Wang S., Sun W., Zhu Y., Du C., Ma R., Wang C. Effect of Cu2O Content in Electrodeposited CuOx Film on Perovskite Solar Cells //Nano. - 2019. - Т 14. - №. 10. - С. 1950126.
12. Polat O., Aytug T., Lupini A.R., Paranthaman P.M., Ertugrul M., Bogorin D.F., Christen D.K. Nanostructured columnar heterostructures of TiO2 and Cu2O enabled by a thin-film selfassembly approach: Potential for photovoltaics // Materials Research Bulletin. 2013. V. 48. №2. P. 352-356.
13. Shang Y., Guo L. FacetDControlled Synthetic Strategy of Cu2ODBased Crystals for Catalysis and Sensing // Advanced Science. 2015. V. 2. №10. P 1500140.
14. Zeng Z., Yan Y., Chen J., Zan P., Tian Q., Chen P. Boosting the photocatalytic ability of Cu2O nanowires for CO2 conversion by MXene quantum dots // Advanced Functional Materials. 2019. V. 29. №2. P. 1806500.
15. Robatjazi H., Zhao H., Swearer D.F., Hogan N.J., Zhou L., Alabastri A., Halas N.J. Plasmon-induced selective carbon dioxide conversion on earth-abundant aluminum-cuprous oxide antenna-reactor nanoparticles // Nature communications. 2017. V. 8. №1. P. 1-10.
16. Wu Y A., McNulty I., Liu C., Lau K. C., Liu Q., Paulikas A. P., Rajh T. Facet-dependent active sites of a single Cu2O particle photocatalyst for CO2 reduction to methanol // Nature Energy. 2019. V. 4. №11. P. 957-968.
17. Blackburn B., Hassan I., Zhang C., Blackman C., Holt K., Carmalt C. Aerosol assisted chemical vapour deposition synthesis of copper (I) oxide thin films for CO2 reduction photocatalysis // Journal of Nanoscience and Nanotechnology. 2016. V. 16. №9. P. 10112-10116.
18. Miller E.B., Zahran E.M., Knecht M.R., Bachas L.G. Metal oxide semiconductor nanomaterial for reductive debromination: Visible light degradation of polybrominated diphenyl ethers by Cu2O@ Pd nanostructures // Applied Catalysis B: Environmental. 2017. V. 213. P. 147154.
19. Kumar A., Kumar A., Sharma G., Ala'a H., Naushad M., Ghfar A. A., Stadler F. J. Quaternary magnetic BiOCl/g-C3N4/Cu2O/Fe3O4 nano-junction for visible light and solar powered degradation of sulfamethoxazole from aqueous environment // Chemical Engineering Journal. 2018. V. 334. P. 462-478.
20. Cui W., An W., Liu L., Hu J., Liang Y Novel Cu2O quantum dots coupled flower-like BiOBr for enhanced photocatalytic degradation of organic contaminant // Journal of hazardous materials. 2014. V. 280. P. 417-427.
21. Yu X., Zhang J., Zhang J., Niu J., Zhao J., Wei Y, Yao B. Photocatalytic degradation of ciprofloxacin using Zn-doped Cu2O particles: analysis of degradation pathways and intermediates // Chemical Engineering Journal. 2019. V. 374. P. 316-327.
22. Cui Y., Wang C., Liu G., Yang H., Wu S., Wang T. Fabrication and photocatalytic property of ZnO nanorod arrays on Cu2O thin film // Materials Letters. 2011. V. 65. №14. P. 2284-2286.
23. Chen R., Lu J., Wang Z., Zhou Q., Zheng M. Microwave synthesis of Cu/Cu2O/SnO2 composite with improved photocatalytic ability using SnCl4 as a protector // Journal of Materials Science. 2018. V. 53. №13. P. 9557-9566.
24. Grondahl L.O. The copper-cuprous-oxide rectifier and photoelectric cell // Reviews of Modern Physics. 1933. V. 5. №2. P. 141.
25. Omelchenko S.T., Tolstova Y, Atwater H.A., Lewis N.S. Excitonic effects in emerging photovoltaic materials: A case study in Cu2O // ACS Energy Letters. 2017. V. 2. №2. P. 431-437.
26. Hu P., Du W., Wang M., Wei H., Ouyang J., Qian Z., Tian Y Reduced bandgap and enhanced p-type electrical conduction in Ag-alloyed Cu2O thin films //Journal of Applied Physics. 2020. V. 128. №12. P. 125302.
27. Izaki M., Fukazawa K., Sato K., Khoo P. L., Kobayashi M., Takeuchi A., Uesugi K. Defect structure and photovoltaic characteristics of internally stacked CuO/Cu2O photoactive layer prepared by electrodeposition and heating // ACS Applied Energy Materials. 2019. V. 2. №7. P. 4833-4840.
28. Zang Z. Efficiency enhancement of ZnO/Cu2O solar cells with well oriented and micrometer grain sized Cu2O films // Applied Physics Letters. 2018. V. 112. №4. P. 042106.
29. Hossain M.I., Alharbi F.H., Tabet N. Copper oxide as inorganic hole transport material for lead halide perovskite based solar cells // Solar Energy. 2015. V. 120. P 370-380.
30. Nejand B.A., Ahmadi V., Gharibzadeh S., Shahverdi H.R. Cuprous oxide as a potential lowcost holeDtransport material for stable perovskite solar cells // ChemSusChem. 2016. V. 9. №. 3. P. 302-313.
31. Guo Y, Lei H., Xiong L., Li B., Chen Z., Wen J., Fang G. Single phase, high hole mobility Cu 2 O films as an efficient and robust hole transporting layer for organic solar cells // Journal of Materials Chemistry A. 2017. V. 5. №22. P. 11055-11062.
32. Elseman A.M., Selim M.S., Luo L., Xu C.Y., Wang G., Jiang Y, Song Q.L. Efficient and Stable Planar nDiDp Perovskite Solar Cells with Negligible Hysteresis through SolutionD Processed Cu2O Nanocubes as a LowDCost HoleDTransport Material // ChemSusChem. 2019. V. 12. №16. P. 3808-3816.
33. Jeong S.S., Mittiga A., Salza E., Masci A., Passerini S. Electrodeposited ZnO/Cu2O heterojunction solar cells // Electrochimica Acta. 2008. V. 53. №5. P. 2226-2231.
34. Soundaram N., Chandramohan R., Valanarasu S., Thomas R., Kathalingam A. Studies on SILAR deposited Cu2O and ZnO films for solar cell applications //Journal of Materials Science: Materials in Electronics. 2015. V. 26. №7. P. 5030-5036.
35. Gershon T., Musselman K.P., Marin A., Friend R.H., MacManus-Driscoll J.L. Thin-film ZnO/Cu2O solar cells incorporating an organic buffer layer // Solar Energy Materials and Solar Cells. 2012. V. 96. P. 148-154.
36. Yu L., Xiong L., Yu Y. Cu2O homojunction solar cells: F-doped N-type thin film and highly improved efficiency // The Journal of Physical Chemistry C. 2015. V. 119. №40. P. 22803-22811.
37. Naz G., Shamsuddin M., Butt F K., Bajwa S. Z., Khan W. S., Irfan M., Irfan M. Au/Cu2O core/shell nanostructures with efficient photoresponses // Chinese Journal of Physics. 2019. V. 59. P. 307-316.
38. Chang X., Wang T., Zhang P., Wei Y, Zhao J., Gong J. Stable aqueous photoelectrochemical CO2 reduction by a Cu2O dark cathode with improved selectivity for carbonaceous products // Angewandte Chemie International Edition. 2016. V. 55. №31. P. 8840-8845.
39. Yuan Q., Chen L., Xiong M., He J., Luo S. L., Au C.T., Yin S.F. Cu2O/BiVO4 heterostructures: synthesis and application in simultaneous photocatalytic oxidation of organic dyes and reduction of Cr (VI) under visible light // Chemical Engineering Journal. 2014. V. 255. P 394-402.
40. Omrani N., Nezamzadeh-Ejhieh A. A comprehensive study on the enhanced photocatalytic activity of Cu2O/BiVO4/WO3 nanoparticles // Journal of Photochemistry and Photobiology A: Chemistry. 2020. V. 389. P. 112-223.
41. Liu A., Zhu Y, Li K., Chu D., Huang J., Li X., Du Y A high-performance p-type nickel oxide/cuprous oxide nanocomposite with heterojunction as the photocathodic catalyst for water splitting to produce hydrogen // Chemical Physics Letters. 2018. V. 703. P. 56-62.
42. Li H., Lei Y, Huang Y, Fang Y, Xu Y, Zhu L., Li X. Photocatalytic reduction of carbon dioxide to methanol by Cu2O/SiC nanocrystallite under visible light irradiation // Journal of Natural Gas Chemistry. 2011. V. 20. №2. P. 145-150.
43. Li Y, Wang W. N., Zhan Z., Woo M. H., Wu C. Y, Biswas P Photocatalytic reduction of CO2 with H2O on mesoporous silica supported Cu/TiO2 catalysts // Applied Catalysis B: Environmental. 2010. V. 100. №1-2. P. 386-392.
44. Guo L., Cao J., Zhang J., Hao Y., Bi K. Photoelectrochemical CO2 reduction by Cu2O/Cu2S hybrid catalyst immobilized in TiO2 nanocavity arrays // Journal of Materials Science. 2019. V. 54. №14. P. 10379-10388.
45. Zhou C., Wang S., Zhao Z., Shi Z., Yan S., Zou Z. A FacetDDependent Schottky D. Junction Electron Shuttle in a BiVO4 {010}-Au-Cu2O ZDScheme Photocatalyst for Efficient Charge Separation // Advanced Functional Materials. 2018. V. 28. №31. P. 1801214.
46. Zhang W., Shi L., Tang K., Dou S. Controllable synthesis of Cu2O microcrystals via a complexant - assisted synthetic route. 2010.
47. Chang P.Y., Tseng I.H. Photocatalytic conversion of gas phase carbon dioxide by graphitic carbon nitride decorated with cuprous oxide with various morphologies // Journal of CO2 Utilization. 2018. V. 26. P. 511-521.
48. Ojha N., Bajpai A., Kumar S. Enriched oxygen vacancies of Cu2O/SnS2/SnO2 heterostructure for enhanced photocatalytic reduction of CO2 by water and nitrogen fixation // Journal of Colloid and Interface Science. 2021. V. 585. P. 764-777.
49. Li P., Jing H., Xu J., Wu C., Peng H., Lu J., Lu F. High-efficiency synergistic conversion of CO 2 to methanol using Fe 2 O 3 nanotubes modified with double-layer Cu 2 O spheres // Nanoscale. 2014. V. 6. №19. P. 11380-11386.
50. Lu Y., Zhang X., Chu Y, Yu H., Huo M., Qu J., Yuan X. Cu2O nanocrystals/TiO2 microspheres film on a rotating disk containing long-afterglow phosphor for enhanced round-the- clock photocatalysis // Applied Catalysis B: Environmental. 2018. V. 224. P. 239-248.
51. Li B., Niu W., Cheng Y, Gu J., Ning P., Guan Q. Preparation of Cu2O modified TiO2 nanopowder and its application to the visible light photoelectrocatalytic reduction of CO2 to CH3OH // Chemical Physics Letters. 2018. V. 700. P. 57-63.
52. Kulandaivalu T., Rashid S. A., Sabli N., Tan T. L. Visible light assisted photocatalytic reduction of CO2 to ethane using CQDs/Cu2O nanocomposite photocatalyst // Diamond and Related Materials. 2019. V. 91. P. 64-73.
53. Masegi H., Goto H., Sadale S. B., Noda K. Real-time monitoring of photocatalytic methanol decomposition over Cu2O-loaded TiO2 nanotube arrays in high vacuum // Journal of Vacuum Science & Technology B, Nanotechnology and Microelectronics: Materials, Processing, Measurement, and Phenomena. 2020. V. 38. №5. P. 052401.
54. Fujita S.I., Kawamori H., Honda D., Yoshida H., Arai M. Photocatalytic hydrogen production from aqueous glycerol solution using NiO/TiO2 catalysts: Effects of preparation and reaction conditions // Applied Catalysis B: Environmental. 2016. V. 181. P. 818-824.
55. Tawfik W.Z., Hassan M.A., Johar M.A., Ryu S.W., Lee J.K. Highly conversion efficiency of solar water splitting over p-Cu2O/ZnO photocatalyst grown on a metallic substrate // Journal of Catalysis. 2019. V. 374. P. 276-283.
56. Carrier M., Perol N., Herrmann J. M., Bordes C., Horikoshi S., Paisse J. O., Guillard C. Kinetics and reactional pathway of Imazapyr photocatalytic degradation Influence of pH and metallic ions // Applied Catalysis B: Environmental. 2006. V. 65. №1-2. P. 11-20.
57. Wang M., Sun L., Lin Z., Cai J., Xie K., Lin C. p-n Heterojunction photoelectrodes composed of Cu 2 O-loaded TiO 2 nanotube arrays with enhanced photoelectrochemical and photoelectrocatalytic activities // Energy & Environmental Science. 2013. V. 6. №4. P. 1211-1220.
58. Wang Y., Shang X., Shen J., Zhang Z., Wang D., Lin J., Li C. Direct and indirect Z- scheme heterostructure-coupled photosystem enabling cooperation of CO2 reduction and H2O oxidation // Nature communications. 2020. V. 11. №1. P. 1-11.
59. Deng X., Zhang Q., Zhou E., Ji C., Huang J., Shao M., Xu X. Morphology transformation of Cu2O sub-microstructures by Sn doping for enhanced photocatalytic properties // Journal of Alloys and Compounds. 2015. V. 649. P. 1124-1129.
60. Ping T., Mihua S., Chengwen S., Shuaihua W., Murong C. Enhanced photocatalytic activity of Cu2O/Cu heterogeneous nanoparticles synthesized in aqueous colloidal solutions on degradation of methyl orange // Rare Metal Materials and Engineering. 2016. V. 45. №9. P. 2214-2218.
61. Shi Y., Yang Z., Wang B., An H., Chen Z., Cui H. Adsorption and photocatalytic degradation of tetracycline hydrochloride using a palygorskite-supported Cu2O-TiO2 composite // Applied Clay Science. 2016. V. 119. P. 311-320.
62. Tang Q., Wu W., Zhang B., Luo J., Zhang H., Guo X., Cao J. A novel in situ synthesis of Cu/Cu2O/CuO/sulfonated polystyrene heterojunction photocatalyst with enhanced photodegradation activity // Journal of Inorganic and Organometallic Polymers and Materials. 2019. V. 29. №2. P. 340-345.
63. An J., Zhou Q. Degradation of some typical pharmaceuticals and personal care products with copper-plating iron doped Cu2O under visible light irradiation // Journal of Environmental Sciences. 2012. V. 24. №5. P. 827-833.
64. Zhu Q., Zhang Y., Lv F., Chu P.K., Ye Z., Zhou F. Cuprous oxide created on sepiolite: preparation, characterization, and photocatalytic activity in treatment of red water from 2, 4, 6- trinitrotoluene manufacturing // Journal of Hazardous Materials. 2012. V. 217. P. 11-18.
65. Zhang A.Y, He Y.Y, Lin T., Huang N.H., Xu Q., Feng J.W. A simple strategy to refine Cu2O photocatalytic capacity for refractory pollutants removal: Roles of oxygen reduction and Fe (II) chemistry // Journal of hazardous materials. 2017. V. 330. P. 9-17.
66. Huang Z., Dai X., Huang Z., Wang T., Cui L., Ye J., Wu P Simultaneous and efficient photocatalytic reduction of Cr (VI) and oxidation of trace sulfamethoxazole under LED light by rGO@ Cu2O/BiVO4 pn heterojunction composite // Chemosphere. 2019. V. 221. P. 824-833. Falah M., MacKenzie K.J.D. Synthesis and properties of novel photoactive composites of P25 titanium dioxide and copper (I) oxide with inorganic polymers // Ceramics International. 2015. V. 41. №10. P. 13702-13708.
67. Zhang Z., Zhai S., Wang M., Ji H., He L., Ye C., Zhang H. Photocatalytic degradation of rhodamine B by using a nanocomposite of cuprous oxide, three-dimensional reduced graphene oxide, and nanochitosan prepared via one-pot synthesis // Journal of Alloys and Compounds. 2016. V. 659. P. 101-111.
68. Anku W.W., Shukla S.K., Govender P.P. Graft Gum Ghatti Caped Cu2O nanocomposite for photocatalytic degradation of naphthol blue black dye // Journal of Inorganic and Organometallic Polymers and Materials. 2018. V. 28. №4. P. 1540-1551.
69. Razmara Z., Poorsargol M. Ultrasonic - assisted synthesis of supramolecular copper (II) complex a precursor for the preparation of octahedron Cu2O nanoparticles applicable in the adsorption and photodegradation of Rhodamine B // Applied Organometallic Chemistry. 2019. V. 33. №9. P e5084.
70. Xu Q., Huang Z., Ji S., Zhou J., Shi R., Shi W. Cu2O nanoparticles grafting onto PLA fibers via electron beam irradiation: bifunctional composite fibers with enhanced photocatalytic of organic pollutants in aqueous and soil systems // Journal of Radioanalytical and Nuclear Chemistry. 2020. V. 323. №1. P. 253-261.
Размещено на Allbest.ru
...Подобные документы
Create a source of light in Earth orbit. Energy source for the artificial sun. Development of light during nucleosynthesis. Using fusion reactors. Application lamp in the center of a parabolic mirror. Application of solar panels and nuclear reactors.
презентация [2,7 M], добавлен 26.05.2014The properties of conductors of electricity. The electric field is as the forces in the space around a charged body. Diagrams of the electric field and the lines of force in the neighborhoods of charged bodies, the elements of an electrical condenser.
презентация [2,0 M], добавлен 13.01.2012The properties of the proton clusters in inelastic interactions SS. Relativistic nuclear interaction. Studying the properties of baryon clusters in a wide range of energies. Seeing the high kinetic energy of the protons in the rest of the cluster.
курсовая работа [108,6 K], добавлен 22.06.2015Reducing the noise and vibrations by using hydraulic absorbers as dampers to dissipate the energy of oscillations in railway electric equipments. The phenomenon of the phase synchronization. Examples of stable and unstable regimes of synchronization.
статья [153,4 K], добавлен 25.03.2011The photoelectric effect. The maximum kinetic energy. Putting it all together. Can we use this idea in a circuit. The results of the photoelectric effect allowed us to look at light completely different. The electron microscope. Wave-particle duality.
презентация [2,3 M], добавлен 06.04.2016Defining the role of the microscope in studies of the structure of nanomaterials. Familiarization with the technology of micromechanical modeling. The use of titanium for studying the properties of electrons. Consideration of the benefits of TEAM project.
реферат [659,8 K], добавлен 25.06.2010A cosmological model to explain the origins of matter, energy, space, time the Big Bang theory asserts that the universe began at a certain point in the distant past. Pre-twentieth century ideas of Universe’s origins. Confirmation of the Big Bang theory.
реферат [37,2 K], добавлен 25.06.2010The danger of cavitation and surface elements spillway structures in vertical spillway. Method of calculation capacity for vortex weirs with different geometry swirling device, the hydraulic resistance and changes in specific energy swirling flow.
статья [170,4 K], добавлен 22.06.2015The overall architecture of radio frequency identification systems. The working principle of RFID: the reader sends out radio waves of specific frequency energy to the electronic tags, tag receives the radio waves. Benefits of contactless identification.
курсовая работа [179,1 K], добавлен 05.10.2014Background to research and investigation of rural electrification. Method of investigation, plan of development, Rampuru, a typical rural South African village. Permanent magnet generator, properties of permanent magnets and evidence of wind resource.
курсовая работа [763,2 K], добавлен 02.09.2010Study of synthetic properties of magnetic nanoparticles. Investigation of X-ray diffraction and transmission electron microscopy of geometrical parameters and super conducting quantum interference device magnetometry of magnetic characterization.
реферат [857,0 K], добавлен 25.06.2010Consideration of the need to apply nanotechnology in agriculture to improve nutrition in the soil, management of toxic elements in the hydrosphere, monitoring the ecological state of land, spraying of mineral substances, purifying water surfaces.
реферат [12,3 M], добавлен 25.06.2010The Rational Dynamics. The Classification of Shannon Isomorphisms. Problems in Parabolic Dynamics. Fundamental Properties of Hulls. An Application to the Invertibility of Ultra-Continuously Meager Random Variables. Fundamental Properties of Invariant.
диссертация [1,6 M], добавлен 24.10.2012Determination of wave-length laser during the leadthrough of experiment in laboratory terms by means of diagnostics of laser ray through the unique diffraction of cut. Analysis of results: length of fringe, areas and interrelation between factors.
лабораторная работа [228,4 K], добавлен 29.12.2010Ukraine is an energy-rich republic. Renewable energy installed capacities. Geothermal energy refers to the heat within the earth’s surface that can be recovered and used for practical purposes. Potential for wind power and Solar energy, their use.
эссе [146,3 K], добавлен 20.03.2011Climate change risks for energy sector companies, climate change governmental, institutional policies impact on energy companies operations. Energy companies reactions to climate change issues: strategies, business decisions. Adapting to climate change.
курсовая работа [1,0 M], добавлен 23.10.2016Написaние прoграммы, выполняющей трансляцию с языка программирования Пaскaль нa язык прoгрaммирoвaния Си и транслирующей конструкции, такие кaк integer, repeat … until Le, procedure, type, record для type. Обработка арифметических и логических выражений.
курсовая работа [314,3 K], добавлен 03.07.2011Prospects for reformation of economic and legal mechanisms of subsoil use in Ukraine. Application of cyclically oriented forecasting: modern approaches to business management. Preconditions and perspectives of Ukrainian energy market development.
статья [770,0 K], добавлен 26.05.2015Формализованное описание закона Pearson Type V. Характеристика методов получения выборки с распределением Pearson Type V. Исследование временных рядов с шумом заданным Rayleigh. Экспериментальное исследование средней трудоемкости Pirson Type V и Rayleigh.
курсовая работа [4,5 M], добавлен 20.06.2010Study of the basic grammatical categories of number, case and gender in modern English language with the use of a field approach. Practical analysis of grammatical categories of the English language on the example of materials of business discourse.
магистерская работа [273,3 K], добавлен 06.12.2015
