Prof Henry Snaith FRS

The phosphine oxide route toward lead halide perovskite nanocrystals

Journal of the American Chemical Society American Chemical Society 140:44 (2018) 14878-14886

Authors:

G Almeida, Olivia Ashton, L Goldoni, D Maggioni, U Petralanda, N Mishra, QA Akkerman, I Infante, Henry J Snaith, L Manna

Abstract:

We report an amine-free synthesis of lead halide perovskite (LHP) nanocrystals, using trioctylphosphine oxide (TOPO) instead of aliphatic amines, in combination with a protic acid (e.g., oleic acid). The overall synthesis scheme bears many similarities to the chemistry behind the preparation of LHP thin films and single crystals, in terms of ligand coordination to the chemical precursors. The acidity of the environment and hence the extent of protonation of the TOPO molecules tune the reactivity of the PbX2 precursor, regulating the size of the nanocrystals. On the other hand, TOPO molecules are virtually absent from the surface of our nanocrystals, which are simply passivated by one type of ligand (e.g., Cs-oleate). Furthermore, our studies reveal that Cs-oleate is dynamically bound to the surface of the nanocrystals and that an optimal surface coverage is critical for achieving high photoluminescence quantum yield. Our scheme delivers NCs with a controlled size and shape: only cubes are formed, with no contamination with platelets, regardless of the reaction conditions that were tested. We attribute such a shape homogeneity to the absence of primary aliphatic amines in our reaction environment, since these are known to promote the formation of nanocrystals with sheet/platelet morphologies or layered phases under certain reaction conditions. The TOPO route is particularly appealing with regard to synthesizing LHP nanocrystals for large-scale manufacturing, as the yield in terms of material produced is close to the theoretical limit: i.e., almost all precursors employed in the synthesis are converted into nanocrystals.

Hysteresis Index: A Figure without Merit for Quantifying Hysteresis in Perovskite Solar Cells

ACS Energy Letters American Chemical Society (ACS) 3:10 (2018) 2472-2476

Authors:

Severin N Habisreutinger, Nakita K Noel, Henry J Snaith

New generation hole transporting materials for Perovskite solar cells: Amide-based small-molecules with nonconjugated backbones

Advanced Energy Materials Wiley 8:32 (2018) 1801605

Authors:

ML Petrus, Kelly Schutt, MT Sirtl, EM Hutter, AC Closs, James Ball, JC Bijleveld, A Petrozza, T Bein, TJ Dingemans, TJ Savenije, H Snaith, P Docampo

Abstract:

State-of-the-art perovskite-based solar cells employ expensive, organic hole transporting materials (HTMs) such as Spiro-OMeTAD that, in turn, limits the commercialization of this promising technology. Herein an HTM (EDOT-Amide-TPA) is reported in which a functional amide-based backbone is introduced, which allows this material to be synthesized in a simple condensation reaction with an estimated cost of <$5 g−1. When employed in perovskite solar cells, EDOT-Amide-TPA demonstrates stabilized power conversion efficiencies up to 20.0% and reproducibly outperforms Spiro-OMeTAD in direct comparisons. Time resolved microwave conductivity measurements indicate that the observed improvement originates from a faster hole injection rate from the perovskite to EDOT-Amide-TPA. Additionally, the devices exhibit an improved lifetime, which is assigned to the coordination of the amide bond to the Li-additive, offering a novel strategy to hamper the migration of additives. It is shown that, despite the lack of a conjugated backbone, the amide-based HTM can outperform state-of-the-art HTMs at a fraction of the cost, thereby providing a novel set of design strategies to develop new, low-cost HTMs.

Perovskite based optoelectronics: molecular design perspectives – a themed collection

Molecular Systems Design & Engineering Royal Society of Chemistry (RSC) 3:5 (2018) 700-701

Authors:

Nakita K Noel, Henry J Snaith

Unravelling the improved electronic and structural properties of methylammonium lead iodide deposited from acetonitrile

Chemistry of Materials American Chemical Society 30:21 (2018) 7737-7743

Authors:

Alexandra Ramadan, Nakita K Noel, S Fearn, Neil Young, M Walker, LA Rochford, Henry J Snaith

Abstract:

Perovskite-based photovoltaics are an emerging solar technology with lab scale device efficiencies of over 22 %, and significant steps are being made toward their commercialization. Conventionally high efficiency perovskite solar cells are formed from high boiling point, polar aprotic solvent solutions. Methylammonium lead iodide (CH3NH3PbI3) films can be made from a range of solvents and blends; however, the role the solvent system plays in determining the properties of the resulting perovskite films is poorly understood. Acetonitrile (ACN), in the presence of methylamine (MA), is a viable nontoxic solvent for fabrication of CH3NH3PbI3 photovoltaic devices with efficiencies >18 %. Herein we examine films prepared from ACN/MA and dimethylformamide (DMF) and scrutinize their physical and electronic properties using spectroscopy, scanning probe imaging, and ion scattering. Significant differences are observed in the chemistry and electronic structure of CH3NH3PbI3 films made with each solvent, ACN/MA produces films with superior properties resulting in more efficient photovoltaic devices. Here we present a holistic and complete understanding of a high performance perovskite material from an electronic, physical, and structural perspective and establish a robust toolkit with which to understand and optimize photovoltaic perovskites.