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Optical Modeling of Copper Oxide Nanoleaves Synthesized by Hot Water Treatment

Published online by Cambridge University Press:  03 July 2020

Khalidah H. Al-Mayalee*
Affiliation:
Physics Department, Faculty of Education for Girels, University of Kufa, Najaf, Iraq Department of Physics and Astronomy, University of Arkansas at Little Rock, Little Rock, AR72204, USA
Tansel Karabacak
Affiliation:
Department of Physics and Astronomy, University of Arkansas at Little Rock, Little Rock, AR72204, USA
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Abstract

In this study, optical absorption properties of copper oxide (II) (CuO) nanoleaf structures grown by hot water treatment (HWT) method were investigated by a numerical simulation method and were compared to experimental results. For this purpose, 3D CuO nanoleaves (NLs) were synthesized by HWT, which simply involved immersing a Cu plate or thin film sample in hot deionized (DI) water. For comparison, we prepared a conventional CuO thin film by thermal oxidation of copper film at about 300 °C. Optical transmission and reflection were measured by UV/Vis/NIR (ultraviolet-visible-near-infrared) spectrophotometer, which were used to calculate optical absorptance. Numerical simulation was performed with finite difference time domain (FDTD) simulation software. Reflectance, transmittance, and absorptance of CuO NLs of different roughness (i.e. CuO NLs layer thickness) were calculated through FDTD method and compared with the experimental results. FDTD simulations predict that nanoleaves morphology enhances light absorption by improving diffuse light scattering and light trapping properties which effectively increases the optical path length without using more material as compared to the thin film structure. This can be useful for developing thinner nanostructured optoelectronic devices with low cost and high efficiency.

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Articles
Copyright
Copyright © Materials Research Society 2020

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References

Rudan, M., Physics of semiconductor devices. 2015: Springer.Google Scholar
Tran, T.H. and Nguyen, V.T., Copper oxide nanomaterials prepared by solution methods, some properties, and potential applications: A brief review. International Scholarly Research Notices, 2014. 2014.CrossRefGoogle ScholarPubMed
Suleiman, M., et al. , Copper (II)-oxide nanostructures: synthesis, characterizations and their applications–review. Journal of Materials and Environmental Science, 2013. 4(5): p. 792-797.Google Scholar
Zhuiykov, S., Nanostructured Semiconductors. 2018: Woodhead Publishing.Google Scholar
Cansizoglu, H., Glad nanostructured arrays with enhanced carrier collection and light trapping for photoconductive and photovoltaic device applications. 2014, University of Arkansas at Little Rock.Google Scholar
Jeevanandam, J., et al. , Review on nanoparticles and nanostructured materials: history, sources, toxicity and regulations. Beilstein journal of nanotechnology, 2018. 9(1): p. 1050-1074.CrossRefGoogle ScholarPubMed
Cansizoglu, H., et al. , Optical absorption properties of semiconducting nanostructures with different shapes. Advanced Optical Materials, 2013. 1(2): p. 158-166.CrossRefGoogle Scholar
Brozak, M., High Performance Glad Nanorod CuInxGa (1-x) Se2 Arrays with Enhanced Carrier Collection and Light Trappingfor Photodetector Applications. 2018, University of Arkansas at Little Rock.Google Scholar
Zhang, Q., et al. , CuO nanostructures: synthesis, characterization, growth mechanisms, fundamental properties, and applications. Progress in Materials Science, 2014. 60: p. 208-337.CrossRefGoogle Scholar
Umar, A., Vaseem, M., and Hahn, Y.-B., Growth, , Properties, and Applications o f Copper Oxide and Nickel Oxide/Hydroxide Nanostructures. American Scientifi c Publishers, 2010. 2: p. 1-39.Google Scholar
Sabbaghan, M., Shahvelayati, A.S., and Madankar, K., CuO nanostructures: Optical properties and morphology control by pyridinium-based ionic liquids. Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 2015. 135: p. 662-668.CrossRefGoogle ScholarPubMed
Zhang, X., et al. , Different CuO nanostructures: synthesis, characterization, and applications for glucose sensors. The Journal of Physical Chemistry C, 2008. 112(43): p. 16845-16849.CrossRefGoogle Scholar
Al-Mayalee, K.H., et al. , Optical and Photoconductive Response of CuO Nanostructures Grown by a Simple Hot-Water Treatment Method. The Journal of Physical Chemistry C, 2018. 122(41): p. 23312-23320.CrossRefGoogle Scholar
Khun, K., Synthesising Metal Oxide Materials and Their Composite Nanostructures for Sensing and Optoelectronic Device Applications. 2014, Linköping University Electronic Press.Google Scholar
Zoolfakar, A.S., et al. , Nanostructured copper oxide semiconductors: a perspective on materials, synthesis methods and applications. Journal of Materials Chemistry C, 2014. 2(27): p. 5247-5270.CrossRefGoogle Scholar
Wong, T.K., et al. , Current status and future prospects of copper oxide heterojunction solar cells. Materials, 2016. 9(4): p. 271.CrossRefGoogle ScholarPubMed
Pandiyarajan, T., et al. , Sonochemical synthesis of CuO nanostructures and their morphology dependent optical and visible light driven photocatalytic properties. Journal of Materials Science: Materials in Electronics, 2017. 28(3): p. 2448-2457.Google Scholar
Deng, X., et al. , Low-temperature solution synthesis of CuO/Cu 2 O nanostructures for enhanced photocatalytic activity with added H2O2: synergistic effect and mechanism insight. RSC Advances, 2017. 7(8): p. 4329-4338.CrossRefGoogle Scholar
Rokhmat, M., et al. , Performance improvement of TiO2/CuO solar cell by growing copper particle using fix current electroplating method. Procedia Engineering, 2017. 170: p. 72-77.CrossRefGoogle Scholar
Luo, L.-B., et al. , One-dimensional CuO nanowire: synthesis, electrical, and optoelectronic devices application. Nanoscale research letters, 2014. 9(1): p. 1-8.CrossRefGoogle ScholarPubMed
Liu, C., et al. , Fast Multiphase Analysis: Self-Separation of Mixed Solution by a Wettability-Controlled CuO@ Ag SERS Substrate and Its Applications in Pollutant Detection. Sensors and Actuators B: Chemical, 2020. 307: p. 127663.CrossRefGoogle Scholar
Siddiqui, H., et al. , Utility of copper oxide nanoparticles (CuO-NPs) as efficient electron donor material in bulk-heterojunction solar cells with enhanced power conversion efficiency. Journal of Science: Advanced Materials and Devices, 2020. 5(1): 104-110.Google Scholar
Liu, J., et al. , Tailoring CuO nanostructures for enhanced photocatalytic property. Journal of colloid and interface science, 2012. 384(1): p. 1-9.CrossRefGoogle ScholarPubMed
Sonia, S., et al. , Hydrothermal synthesis of highly stable CuO nanostructures for efficient photocatalytic degradation of organic dyes. Materials Science in Semiconductor Processing, 2015. 30: p. 585-591.CrossRefGoogle Scholar
Grigore, M.E., et al. , Methods of Synthesis, Properties and Biomedical Applications of CuO Nanoparticles. Pharmaceuticals, 2016. 9(4): p. 75.CrossRefGoogle ScholarPubMed
Khedir, K.R., et al. , Robust superamphiphobic nanoscale copper sheet surfaces produced by a simple and environmentally friendly technique. Advanced Engineering Materials, 2015. 17(7): p. 982-989.CrossRefGoogle Scholar
García Marín, A., et al. , Fast response ZnO: Al/CuO nanowire/ZnO: Al heterostructure light sensors fabricated by dielectrophoresis. Applied Physics Letters, 2013. 102(23): p. 232105.CrossRefGoogle Scholar
Saadi, N.S., Hassan, L.B., and Karabacak, T., Metal oxide nanostructures by a simple hot water treatment. Scientific Reports, 2017. 7(1).CrossRefGoogle ScholarPubMed
Abdulrahman, R.B., Enhanced light trapping by metallic nanorod arrays for organic photovoltaic cells. 2014, University of Arkansas at Little Rock.Google Scholar
Ma, S., et al. , A theoretical study on the optical properties of black silicon. AIP Advances, 2018. 8(3): p. 035010.CrossRefGoogle Scholar
Paul, S.R. and Metya, S.K.. Importance of FDTD in plasmonic devices. in 2016 IEEE Students' Conference on Electrical, Electronics and Computer Science (SCEECS). 2016. IEEE.CrossRefGoogle Scholar
Chan, P.H., Study of reflectivity calculation errors in FDTD method with large angles of incidence. 2014.Google Scholar
Lumerical Solutions, I. Knowledge Base. 2019; Available from: https://kb.lumerical.com/index.html.Google Scholar
Azzam, R.M.Mueller-matrix ellipsometry: a review. in Polarization: Measurement, Analysis, and Remote Sensing. 1997. International Society for Optics and Photonics.Google Scholar
Jiménez-Solano, A., Carretero-Palacios, S., and Míguez, H., Absorption enhancement in methylammonium lead iodide perovskite solar cells with embedded arrays of dielectric particles. Optics express, 2018. 26(18): p. A865-A878.CrossRefGoogle ScholarPubMed
Padera, F., Measuring absorptance (k) and refractive index (n) of thin films with the perkinelmer lambda 950/1050 high performance UV-Vis/NIR spectrometers. PerkinElmer, Inc, 2013.Google Scholar
HUSSEIN, A.N., et al. , Study on Structure And Optical Properties Of CuO Thin Films Prepared By Chemical Spray Pyrolysis. Journal of Applied Physical Science International, 2015. 4(3): p. 178-184.Google Scholar
Lumerical, F., Solutions. 2016.Google Scholar
Ozdemir, A. and Kocer, H., Near-Infrared Tunable Reflection and Absorption Using Nanostructured Thin Film Structures Employing Phase-Change Material. Acta Physica Polonica A, 2016. 129(4): p. 464-467.CrossRefGoogle Scholar
Brongersma, M.L., Cui, Y., and Fan, S., Light management for photovoltaics using high-index nanostructures. Nature materials, 2014. 13(5): p. 451-460.CrossRefGoogle ScholarPubMed
Guo, T., et al. , Design of antireflective coatings for AZO low infrared emissivity layer. Vol. 11. 2013.Google Scholar
Al-Mayalee, K.H., et al. , CuO/Cu core/shell nanostructured photoconductive devices by hot water treatment and high pressure sputtering techniques. Nanotechnology, 2020. 31(9): p. 095204.CrossRefGoogle ScholarPubMed
Scholtz, Ľ., Ladanyi, L., and Müllerová, J., Influence of surface roughness on optical characteristics of multilayer solar cells. 2014.CrossRefGoogle Scholar
Mageshwari, K. and Sathyamoorthy, R., Flower-shaped CuO nanostructures: synthesis, characterization and antimicrobial activity. Journal of Materials Science & Technology, 2013. 29(10): p. 909-914.CrossRefGoogle Scholar
Jeong, D., et al. , Absorption mechanism and performance characterization of CuO nanostructured absorbers. Solar Energy Materials and Solar Cells, 2017. 169: p. 270-279.CrossRefGoogle Scholar
Wang, W., et al. , Large absorption enhancement in ultrathin solar cells patterned by metallic nanocavity arrays. Scientific reports, 2016. 6: p. 34219.CrossRefGoogle ScholarPubMed
O’Donnell, K. and Méndez, E., Enhanced specular peaks in diffuse light scattering from weakly rough metal surfaces. JOSA A, 2003. 20(12): p. 2338-2346.Google Scholar
Metel, A., et al. , Power Density Distribution for Laser Additive Manufacturing (SLM): Potential, Fundamentals and Advanced Applications. Technologies, 2019. 7(1): p. 5.Google Scholar
Leung, S.-F., et al. , Light management with nanostructures for optoelectronic devices. The journal of physical chemistry letters, 2014. 5(8): p. 1479-1495.CrossRefGoogle ScholarPubMed