Evaluation of SnS:Cu Thin Film Properties Obtained by USP Technique to Implement It as an Absorbent Layer in Solar Cells Using SCAPS

Sergio Rodríguez-Castro,Michel Rivero,Bernardo Reyes-Durán,Carlos Álvarez-Macías,Rodrigo Loera-Palomo,Lizbeth Salgado-Conrado,Jorge Narro-Ríos

doi:10.3390/coatings11070754

Abstract

Tin sulfide doped with copper (SnS:Cu) thin films were deposited on glass substrates by the ultrasonic spray pyrolysis (USP) technique at different concentration ratios (y = [Cu]/[Sn] = 0% (undoped), 2%, 5% and 10%). The aim of this work is to analyze the effect of copper on structural, morphological, and optoelectronic properties of SnS:Cu and discuss their possible application as an absorber layer in a solar cell structure proposed which is simulated using SCAPS software. X-ray diffraction (XRD) reveals an orthorhombic structure in the undoped sample and a cubic structure in doped ones. Raman spectroscopy suggests a possible unit cell size change due to the addition of Cu. Scanning electron microscopy (SEM) shows growth in grain density with an increasing y. Image analysis based on second-order features was used to discuss grain distribution. UV-VIS spectroscopy helps to find an increase of bandgap for the doped samples when copper concentration increases, going from 1.82 eV in the doped film y = 2% to 2.2 eV in the 10% doped samples. A value of 3.51 eV was found for the undoped sample y = 0%. A rise in both carrier concentration and mobility but a decrease in resistivity when y is increased was observed through the Hall–Van der Pauw technique. Simulations by SCAPS helped conclude that considering the material thickness, the SnS:Cu compound can be an alternative for implementation in the manufacturing of solar cells as an absorber layer since it is possible to obtain the optoelectronic properties necessary using the UPS economical technique.

Highlights

IntroductionThe investigation of new advanced materials applied to the photovoltaic sector has been an object of study
For over a century, the investigation of new advanced materials applied to the photovoltaic sector has been an object of study
Due to specific optoelectronic characteristics required to an absorbent layer in a solar cell and based on experimental results of the SnS:Cu from this work, this subsection considers comparing the results of the device proposed and simulated using the properties of each SnS:Cu thin film as an absorbent layer excluding the undoped thin film y = 0% due to the consideration of these films causing convergence errors within the SCAPS program, mainly due to their high Eg value

Summary

Introduction

The investigation of new advanced materials applied to the photovoltaic sector has been an object of study. These materials need to exhibit specific properties to be used in optoelectronic devices such as solar cells. Semiconductors like Si or CdTe have shown great efficiency resulting in the production of commercial modules of these types of materials. Semiconductors belonging to the IV-VI group of the periodic table have attracted attention due to their potential use in optical applications. Tin sulfide (SnS) is a binary semiconductor belonging to this group, and it is widely used

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