Semiconductors group

Optoelectronic properties of tin-lead halide perovskites

ACS Energy Letters American Chemical Society 6:7 (2021) 2413-2426

Authors:

Kimberley J Savill, Aleksander M Ulatowski, Laura M Herz

Abstract:

Mixed tin–lead halide perovskites have recently emerged as highly promising materials for efficient single- and multi-junction photovoltaic devices. This Focus Review discusses the optoelectronic properties that underpin this performance, clearly differentiating between intrinsic and defect-mediated mechanisms. We show that from a fundamental perspective, increasing tin fraction may cause increases in attainable charge-carrier mobilities, decreases in exciton binding energies, and potentially a slowing of charge-carrier cooling, all beneficial for photovoltaic applications. We discuss the mechanisms leading to significant bandgap bowing along the tin–lead series, which enables attractive near-infrared bandgaps at intermediate tin content. However, tin-rich stoichiometries still suffer from tin oxidation and vacancy formation which often obscures the fundamentally achievable performance, causing high background hole densities, accelerating charge-carrier recombination, lowering charge-carrier mobilities, and blue-shifting absorption onsets through the Burstein–Moss effect. We evaluate impacts on photovoltaic device performance, and conclude with an outlook on remaining challenges and promising future directions in this area.

Controlling and Understanding the Effects of Crystal Size in Vapor Deposited Metal-Halide Perovskite Solar Cells

Fundacio Scito (2021)

Authors:

Kilian Lohmann, Jay Patel, Mathias Rothmann, Chelsea Xia, Robert Oliver, Laura Herz, Henry Snaith, Michael Johnston

The impact of phase segregation in mixed halide perovskites: a matter of charge recombination rather than transport

Fundacio Scito (2021)

Authors:

Silvia Motti, Jay Patel, Robert Oliver, Henry Snaith, Michael Johnston, Laura Herz

Understanding the crystallographic and microstructural properties of hybrid perovskite thin films through electron microscopy

Fundacio Scito (2021)

Authors:

Mathias Uller Rothmann, Laura Herz, Juliane Borchert, Kilian Lohmann, Colum M. O'Leary, Judy Kim, Laura Clark, Henry Snaith, Michael Johnston, Peter Nellist, Alex Sheader

Polarons and charge localization in metal-halide semiconductors for photovoltaic and light-emitting devices

Advanced Materials Wiley 33:24 (2021) 2007057

Authors:

Leonardo RV Buizza, Laura M Herz

Abstract:

Metal-halide semiconductors have shown excellent performance in optoelectronic applications such as solar cells, light-emitting diodes, and detectors. In this review the role of charge–lattice interactions and polaron formation in a wide range of these promising materials, including perovskites, double perovskites, Ruddlesden–Popper layered perovskites, nanocrystals, vacancy-ordered, and other novel structures, is summarized. The formation of Fröhlich-type “large” polarons in archetypal bulk metal-halide ABX3 perovskites and its dependence on A-cation, B-metal, and X-halide composition, which is now relatively well understood, are discussed. It is found that, for nanostructured and novel metal-halide materials, a larger variation in the strengths of polaronic effects is reported across the literature, potentially deriving from variations in potential barriers and the presence of interfaces at which lattice relaxation may be enhanced. Such findings are further discussed in the context of different experimental approaches used to explore polaronic effects, cautioning that firm conclusions are often hampered by the presence of alternate processes and interactions giving rise to similar experimental signatures. Overall, a complete understanding of polaronic effects will prove essential given their direct influence on optoelectronic properties such as charge-carrier mobilities and emission spectra, which are critical to the performance of energy and optoelectronic applications.