A study of copper–tungsten oxide materials for photovoltaic application

Purpose Even though copper–tungsten has shown signs of potentials, relatively little is currently known about its appropriateness for photovoltaic application. This paper aims to evaluate the suitability of copper-tungs oxides as photovoltaic absorbers while investigating the consequences of oxygen...

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Bibliographic Details
Published in:World journal of engineering 2022-12, Vol.19 (6), p.822-831
Main Authors: Ifeanyi, Ark, Isherwood, Patrick, Abdul-Lateef, Aminat Olawumi
Format: Article
Language:English
Subjects:
Absorbers
Availability
Cadmium telluride
Cadmium tellurides
Chalcogenides
Combinatorial analysis
Copper
Copper base alloys
Copper oxides
Efficiency
Energy storage
Flow velocity
Hydrogen production
Light emitting diodes
Magnetron sputtering
Magnetrons
Manufacturing
Metal oxides
Optical properties
Optimization
Oxygen
Personal computers
Photovoltaic cells
Schottky diodes
Simulation
Solar cells
Spectrophotometry
Thickness
Thin films
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Summary:Purpose Even though copper–tungsten has shown signs of potentials, relatively little is currently known about its appropriateness for photovoltaic application. This paper aims to evaluate the suitability of copper-tungs oxides as photovoltaic absorbers while investigating the consequences of oxygen content variation. Design/methodology/approach Using profilometry, Hall measurements, Seebeck test and spectrophotometry, grown samples were defined. Samples of 5 standard cubic centimeters per minute (sccm) and 7 sccm exhibited appropriate characteristics and were further tested using personal computer one dimension (PC1D) computational simulation at the system stage. To grow materials with an average thickness below 0.45 µm, magnetron co-sputtering was used. Three sample sets, varied by oxygen flow rate, were made with flow rates of 5sccm, 7sccm and 9sccm, respectively. Findings Some samples proved to be effective absorbers, using a cadmium telluride device as the criterion of output calculation, with one sample chosen as ideal for each type of flow rate. For the chosen samples, an optimum thickness was also obtained, i. It was discovered that thinner cells, optimal for both groups with 0.6 µm, performed better to than other thicknesses. Research limitations/implications The material also demonstrated prospects for applications in window layers, but more needs to be known. Practical implications Thin film material properties and their operating processes are relatively complex, so it is important to find simple and cost-effective ways to forecast performance. While relatively new, numerical modeling has proven to be very useful in defining the critical properties of thin film devices, thereby helpful for predictions of performance. Solar cell capacitance simulator one dimension, amorphous semiconductor analysis, personal computer one dimension (PC1D), analysis of micro-electronic and photonic structures and automat for simulation for heterostructures (33) are several common models in the thin film industry. Due to its availability and relative ease of use, PC1D was used in this project. Social implications As the search for the balance among performance, cost, reliability and availability continue, more absorber components continue to evolve, notably from the chalcogenides. Because of their ability to absorb light, ternary transition metal chalcogenides are useful in the production of hydrogen and in the energy storage sector, as well as in the production of l
ISSN:1708-5284
2515-8082
1708-5284
DOI:10.1108/WJE-04-2021-0241