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Performance Optimization of Quantum Well Solar Cells Through Layer Thickness Variation

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Sanjina Mostafa; Mohammad Nadeem; Md. Imran Hossain Arif; Muhammad Johirul Islam; Md. Iqbal Bahar Chowdhury
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Abstract:

This work aims to investigate the effects of thickness variation of the different layers of a quantum well solar cell on its performance parameters i.e. on the short circ...Show More

Metadata

Abstract:

This work aims to investigate the effects of thickness variation of the different layers of a quantum well solar cell on its performance parameters i.e. on the short circuit current and the conversion efficiency. The investigation incurs a number of simulations carried out using the ATLAS tool of Silvaco software. The analysis of the simulated results not only provide a better view as well as a physics-based understanding of the effects of the thickness variation of each layer on the performance parameters but also help optimize these layer thicknesses to achieve the best possible performance, which includes the short circuit current and the conversion efficiency, of a quantum well solar cell.
Published in: 2020 23rd International Conference on Computer and Information Technology (ICCIT)
Date of Conference: 19-21 December 2020
Date Added to IEEE Xplore: 06 April 2021
ISBN Information:
DOI: 10.1109/ICCIT51783.2020.9392741
Conference Location: DHAKA, Bangladesh
References is not available for this document.
Contents

I. Introduction

The trade-off between the maximization of the current and the voltage of solar cells obtained through smaller and larger band-gap-materials respectively sets their fundamental efficiency limit to 31% [1]. Insertion of thin layers of smaller-bandgap material (the quantum well) in a host of larger-bandgap material (the quantum barrier), as shown in Fig. 1, can be a trick to break this fundamental limit [2], [3]. Known as quantum well solar cells (QWSC), this type of solar can harvest longer wavelength photons which are simply transmitted past the thin-film solar cells configured to absorb light with wavelengths approximately 900 nm, also evident from Fig. 1. Early-days QWSCs used p-n structure [2], which are later replaced by the p-i-n structure to provide uniform electric field across all the quantum wells inserted in the i-layer i.e. in the sandwiched intrinsic layer [Fig. 1]. The photo-generated carriers can escape from the wells through the thermal escape and tunneling [4] –[6]. However, the efficiency of QWSC is enhanced in comparison with the bulk cells (which has no quantum wells) when the loss in voltage is counter-balanced by the photo-current enhancement [7]. The work in [8] experimentally verified the voltage enhancement in QWSC; the prospect of enhanced efficiency has been discussed in [9], [10].

Energy band diagram of a quantum well solar cell [11].

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