Prof Henry Snaith FRS

Hole-transport materials with greatly-differing redox potentials give efficient TiO2-[CH3NH3][PbX3] perovskite solar cells

Physical Chemistry Chemical Physics 17:4 (2015) 2335-2338

Authors:

A Abate, M Planells, DJ Hollman, V Barthi, S Chand, HJ Snaith, N Robertson

Abstract:

Two diacetylide-triphenylamine hole-transport materials (HTM) with varying redox potential have been applied in planar junction TiO2-[CH3NH3]PbI3-xClx solar cells leading to high power-conversion efficiencies up to 8.8%. More positive oxidation potential of the HTM gives higher VOC and lower JSC illustrating the role of matching energy levels, however both HTMs gave efficient cells despite a difference of 0.44 V in their redox potentials. This journal is

Hole-transport materials with greatly-differing redox potentials give efficient TiO 2 –[CH 3 NH 3 ][PbX 3 ] perovskite solar cells

Physical Chemistry Chemical Physics Royal Society of Chemistry (RSC) 17:4 (2015) 2335-2338

Authors:

Antonio Abate, Miquel Planells, Derek J Hollman, Vishal Barthi, Suresh Chand, Henry J Snaith, Neil Robertson

The real TiO 2 /HTM interface of solid-state dye solar cells: role of trapped states from a multiscale modelling perspective

Nanoscale Royal Society of Chemistry (RSC) 7:3 (2015) 1136-1144

Authors:

Alessio Gagliardi, Matthias Auf der Maur, Desiree Gentilini, Fabio di Fonzo, Agnese Abrusci, Henry J Snaith, Giorgio Divitini, Caterina Ducati, Aldo Di Carlo

Optical Description of Mesostructured Organic–Inorganic Halide Perovskite Solar Cells

The Journal of Physical Chemistry Letters American Chemical Society (ACS) 6:1 (2015) 48-53

Authors:

Miguel Anaya, Gabriel Lozano, Mauricio E Calvo, Wei Zhang, Michael B Johnston, Henry J Snaith, Hernán Míguez

Charge selective contacts, mobile ions and anomalous hysteresis in organic-inorganic perovskite solar cells

Materials Horizons Royal Society of Chemistry 2:3 (2015) 315-322

Authors:

Ye Zhang, Mingzhen Liu, Giles Eperon, Tomas C Leijtens, David McMeekin, Michael Saliba, Wei Zhang, Michele de Bastiani, Annamaria Petrozza, Laura Herz, Michael Johnston, Hong Lin, Henry J Snaith

Abstract:

High-efficiency perovskite solar cells typically employ an organic–inorganic metal halide perovskite material as light absorber and charge transporter, sandwiched between a p-type electron-blocking organic hole-transporting layer and an n-type hole-blocking electron collection titania compact layer. Some device configurations also include a thin mesoporous layer of TiO2 or Al2O3 which is infiltrated and capped with the perovskite absorber. Herein, we demonstrate that it is possible to fabricate planar and mesoporous perovskite solar cells devoid of an electron selective hole-blocking titania compact layer, which momentarily exhibit power conversion efficiencies (PCEs) of over 13%. This performance is however not sustained and is related to the previously observed anomalous hysteresis in perovskite solar cells. The “compact layer-free” meso-superstructured perovskite devices yield a stabilised PCE of only 2.7% while the compact layer-free planar heterojunction devices display no measurable steady state power output when devoid of an electron selective contact. In contrast, devices including the titania compact layer exhibit stabilised efficiency close to that derived from the current voltage measurements. We propose that under forward bias the perovskite diode becomes polarised, providing a beneficial field, allowing accumulation of positive and negative space charge near the contacts, which enables more efficient charge extraction. This provides the required built-in potential and selective charge extraction at each contact to temporarily enable efficient operation of the perovskite solar cells even in the absence of charge selective n- and p-type contact layers. The polarisation of the material is consistent with long range migration and accumulation of ionic species within the perovskite to the regions near the contacts. When the external field is reduced under working conditions, the ions can slowly diffuse away from the contacts redistributing throughout the film, reducing the field asymmetry and the effectiveness of the operation of the solar cells. We note that in light of recent publications showing high efficiency in devices devoid of charge selective contacts, this work reaffirms the absolute necessity to measure and report the stabilised power output under load when characterizing perovskite solar cells.