Snaith group

The impact of the crystallization processes on the structural and optical properties of hybrid perovskite films for photovoltaics

journal of physical chemistry letters American Chemical Society 5:21 (2014) 3836-3842

Authors:

Giulia Grancini, Sergio Marras, Mirko Prato, Cinzia Giannini, Claudio Quarti, Filippo De Angelis, Michele De Bastiani, Giles Eperon, Henry J Snaith, Liberato Manna, Annamaria Petrozza

Abstract:

We investigate the relationship between structural and optical properties of organo-lead mixed halide perovskite films as a function of the crystallization mechanism. For methylammonium lead tri-iodide, the organic cations rearrange within the inorganic cage, moving from crystals grown in a mesoporous scaffold to larger, oriented crystals grown on a flat substrate. This reduces the strain felt by the bonds forming the cage and affects the motion of the organic cation in it, influencing the electronic transition at the onset of the optical absorption spectrum of the semiconductor. Moreover, we demonstrate that in mixed-halide perovskite, though Cl(-) ions are not present in a detectable concentration in the unit cell, they drive the crystallization dynamics. This induces a preferential order during crystallization, from a molecular, i.e., organic-inorganic moieties arrangement, to a nano-mesoscopic level, i.e., larger crystals with anisotropic shape. Finally, we show that while Cl is mainly expelled from flat films made of large crystals, in the presence of an oxide mesoporous scaffold they are partially retained in the composite.

A transparent conductive adhesive laminate electrode for high-efficiency organic-inorganic lead halide perovskite solar cells.

Advanced materials (Deerfield Beach, Fla.) 26:44 (2014) 7499-7504

Authors:

Daniel Bryant, Peter Greenwood, Joel Troughton, Maarten Wijdekop, Mathew Carnie, Matthew Davies, Konrad Wojciechowski, Henry J Snaith, Trystan Watson, David Worsley

Abstract:

A self-adhesive laminate solar-cell electrode is presented based on a metal grid embedded in a polymer film (x-y conduction) and set in contact with the active layer using a pressure-sensitive adhesive containing a very low quantity (1.8%) of organic conductor, which self-organizes to provide z conduction to the grid. This ITO-free material performs in an identical fashion to evaporated gold in high-efficiency perovskite solar cells.

Sub 150 °C processed meso-superstructured perovskite solar cells with enhanced efficiency (presentation video)

Proceedings of SPIE--the International Society for Optical Engineering SPIE, the international society for optics and photonics 9184 (2014) 91840q-91840q-1

Authors:

Konrad Wojciechowski, Michael Saliba, Tomas Leijtens, Antonio Abate, Henry J Snaith

Solution deposition-conversion for planar heterojunction mixed halide perovskite solar cells

Advanced Energy Materials 4:14 (2014)

Authors:

P Docampo, FC Hanusch, SD Stranks, M Döblinger, JM Feckl, M Ehrensperger, NK Minar, MB Johnston, HJ Snaith, T Bein

Abstract:

Solution-deposited-converted perovskite solar cells are studied by converting PbI2planar films into the phase pure, mixed-halide perovskite (H3CNH3)PbI3-xClx. These solar cells exhibit very high photovoltaic performance and close to unity internal incident photon-to-electron conversion.

Carbon nanotube/polymer composites as a highly stable hole collection layer in perovskite solar cells.

Nano letters 14:10 (2014) 5561-5568

Authors:

Severin N Habisreutinger, Tomas Leijtens, Giles E Eperon, Samuel D Stranks, Robin J Nicholas, Henry J Snaith

Abstract:

Organic-inorganic perovskite solar cells have recently emerged at the forefront of photovoltaics research. Power conversion efficiencies have experienced an unprecedented increase to reported values exceeding 19% within just four years. With the focus mainly on efficiency, the aspect of stability has so far not been thoroughly addressed. In this paper, we identify thermal stability as a fundamental weak point of perovskite solar cells, and demonstrate an elegant approach to mitigating thermal degradation by replacing the organic hole transport material with polymer-functionalized single-walled carbon nanotubes (SWNTs) embedded in an insulating polymer matrix. With this composite structure, we achieve JV scanned power-conversion efficiencies of up to 15.3% with an average efficiency of 10 ± 2%. Moreover, we observe strong retardation in thermal degradation as compared to cells employing state-of-the-art organic hole-transporting materials. In addition, the resistance to water ingress is remarkably enhanced. These are critical developments for achieving long-term stability of high-efficiency perovskite solar cells.