Abstract
Cu 2 ZnSnS 4 (CZTS) is a quaternary semiconductor that has emerged as a promising component in solar absorber materials due to its excellent optical properties such as band-gap energy of ca. 1.5 eV and significant absorption coefficient in the order of 10 4 cm − 1 . Nevertheless, the energy conversion efficiency of CZTS-based devices has not reached the theoretical limits yet, possibly due to the existence of antisite defects (such as Cu Zn or Zn Cu ) and secondary phases. Based on electronic similarities with Zn, Mg has been proposed for Zn substitution in the CZTS structure in the design of alternative semiconductors for thin-film solar cell applications. This work aims to study the properties of the CZTS having Mg incorporated in the structure replacing Zn, with the following stoichiometry: x = 0, 0.25, 0.5, 0.75, and 1 in the formula Cu 2 Zn 1 − x Mg x SnS 4 (CZ-MTS). The semiconductor was prepared by the hot injection method, using oleylamine (OLA) as both surfactant and solvent. The presence and concentration of incorporated Mg allowed the fine-tuning of the CZ-MTS semiconductor’s structural and optical properties. Furthermore, it was observed that the inclusion of Mg in the CZTS structure leads to a better embodiment ratio of the Zn during the synthesis, thus reducing the excess of starting precursors. In summary, CZ-MTS is a promising candidate to fabricate high efficient and cost-effective thin-film solar cells made of earth-abundant elements.
Highlights
The development of sustainable resources to obtain clean energy as an alternative to fossil fuel has become a fundamental challenge of the 21st century, for both industry and academia.Solar energy is one of the best options among all renewable energies able to cover current energy demand
CZTSSe is isoelectronic to CIGS [2], so they share their material properties while all the know-how related to preparation
The purpose of this work is to contribute to the study of Magnesium incorporation in the CZTS, exploring the effects of the partial and complete of substitution Zn by Mg on the CZ-MTS optical and structural properties
Summary
The development of sustainable resources to obtain clean energy as an alternative to fossil fuel has become a fundamental challenge of the 21st century, for both industry and academia.Solar energy is one of the best options among all renewable energies able to cover current energy demand. Significant efforts have been made searching for a cheaper and non-toxic photovoltaic material in order to improve the record efficiency (above 20%) [1,2] of chalcopyrites Cu(In,Ga)Se2 or CIGS [3,4,5]. In this context, kesterites as Cu2 ZnSn(S,Se) (CZTSSe) are attractive and promising materials for absorber layers in thin-film solar cells because all its components are earth-abundant and environment-friendly [6]. The current record efficiency is 12.6% for CZTSSe [3,4,11,12,13] with band gaps between 1.0 and 1.5 eV [11,12], which is still lower than the requirement for commercial solar cell devices
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