Emergence of New Materials for Exploiting Highly Efficient Carrier Multiplication in Photovoltaics

TL;DR

This review discusses recent advances in carrier multiplication in photovoltaics, highlighting new materials like quantum dots and perovskites that could significantly improve solar cell efficiency by utilizing excess photon energy.

Contribution

It identifies key material properties and emerging materials that enable highly efficient carrier multiplication, advancing the understanding and potential applications in solar energy conversion.

Findings

Materials with low exciton binding energy and high mobility facilitate carrier multiplication.

Percolative networks of quantum dots and halide perovskites show promising CM efficiency.

CM threshold approaches minimal values in certain asymmetric electronic transition materials.

Abstract

In conventional solar cell semiconductor materials (predominantly Si) photons with energy higher than the band gap initially generate hot electrons and holes, which subsequently cool down to the band edge by phonon emission. Due to the latter process, the energy of the charge carriers in excess of the band gap is lost as heat and does not contribute to the conversion of solar to electrical power. If the excess energy is more than the band gap it can in principle be utilized through a process known as carrier multiplication (CM) in which a single absorbed photon generates two (or more) pairs of electrons and holes. Thus, through CM the photon energy above twice the band gap enhances the photocurrent of a solar cell. In this review, we discuss recent progress in CM research in terms of fundamental understanding, emergence of new materials for efficient CM, and CM based solar cell applications. Based on our current understanding, the CM threshold can get close to the minimal value of twice the band gap in materials where a photon induces an asymmetric electronic transition from a deeper valence band or to a higher conduction band. In addition, the material must have a low exciton binding energy and high charge carrier mobility, so that photoexcitation leads directly to the formation of free charges that can readily be extracted at external electrodes of a photovoltaic device. Percolative networks of coupled PbSe quantum dots, Sn/Pb based halide perovskites, and transition metal dichalcogenides such as MoTe2 fulfill these requirements to a large extent. These findings point towards promising prospects for further development of new materials for highly efficient photovoltaics.