Prof Henry Snaith FRS

Interlayer excitons in MoSe 2 /2D perovskite hybrid heterostructures – the interplay between charge and energy transfer

Nanoscale Royal Society of Chemistry (RSC) 14:22 (2022) 8085-8095

Authors:

M Karpińska, J Jasiński, R Kempt, JD Ziegler, H Sansom, T Taniguchi, K Watanabe, HJ Snaith, A Surrente, M Dyksik, DK Maude, Ł Kłopotowski, A Chernikov, A Kuc, M Baranowski, P Plochocka

Improving performance of fully scalable, flexible transparent conductive films made from carbon nanotubes and ethylene-vinyl acetate

Energy Reports Elsevier 8:S11 (2022) 48-60

Authors:

Bernd K Sturdza, Andreas E Lauritzen, Suer Zhou, Andre J Bennett, Joshua Form, M Greyson Christoforo, Robert M Dalgliesh, Henry J Snaith, Moritz K Riede, Robin J Nicholas

Abstract:

We report process improvements for the fabrication of single-walled carbon nanotube ethylene-vinyl acetate transparent conductive films. CNT:EVA films demonstrate high resilience against folding and can replace the external dopant in a spiro-OMeTAD based hole selective contact of n-i-p perovskite solar cells achieving a steady-state efficiency of 16.3%. The adapted process is fully scalable, and compared to previous reports (Mazzotta et al., 2018) lowers the material cost dramatically and improves DC to optical conductivity ratio by two orders of magnitude to σdc/σop = 3.6 for pristine and σdc/σop = 15 for chemically doped films. We analyse the microstructure of our films via small angle neutron scattering and find a positive correlation between the long range packing density of the CNT:EVA films and the σdc/σop performance. Increasing monomer ratio and chain length of the EVA polymer improves resilience against bending strain, whereas no significant effect on the CNT wrapping and electrical conductivity of resulting films is found.

Scalable processing for realizing 21.7%-efficient all-perovskite tandem solar modules

Science American Association for the Advancement of Science 376:6594 (2022) 762-767

Authors:

Ke Xiao, Yen-Hung Lin, Mei Zhang, Robert DJ Oliver, Xi Wang, Zhou Liu, Xin Luo, Jia Li, Donny Lai, Haowen Luo, Renxing Lin, Jun Xu, Yi Hou, Henry J Snaith, Hairen Tan

Abstract:

Challenges in fabricating all-perovskite tandem solar cells as modules rather than as single-junction configurations include growing high-quality wide-bandgap perovskites and mitigating irreversible degradation caused by halide and metal interdiffusion at the interconnecting contacts. We demonstrate efficient all-perovskite tandem solar modules using scalable fabrication techniques. By systematically tuning the cesium ratio of a methylammonium-free 1.8–electron volt mixed-halide perovskite, we improve the homogeneity of crystallization for blade-coated films over large areas. An electrically conductive conformal “diffusion barrier” is introduced between interconnecting subcells to improve the power conversion efficiency (PCE) and stability of all-perovskite tandem solar modules. Our tandem modules achieve a certified PCE of 21.7% with an aperture area of 20 square centimeters and retain 75% of their initial efficiency after 500 hours of continuous operation under simulated 1-sun illumination.

Solvent-free method for defect reduction and improved performance of p-i-n vapor-deposited perovskite solar cells

ACS Energy Letters American Chemical Society 7 (2022) 1903-1911

Authors:

Kilian Lohmann, Silvia G Motti, Robert DJ Oliver, Alexandra J Ramadan, Harry C Sansom, Qimu Yuan, Karim A Elmestekawy, James M Ball, Laura M Herz, Henry J Snaith, Michael Johnston

Abstract:

As perovskite-based photovoltaics near commercialization, it is imperative to develop industrial-scale defect-passivation techniques. Vapor deposition is a solvent-free fabrication technique that is widely implemented in industry and can be used to fabricate metal-halide perovskite thin films. We demonstrate markably improved growth and optoelectronic properties for vapor-deposited [CH(NH2)2]0.83Cs0.17PbI3 perovskite solar cells by partially substituting PbI2 for PbCl2 as the inorganic precursor. We find the partial substitution of PbI2 for PbCl2 enhances photoluminescence lifetimes from 5.6 ns to over 100 ns, photoluminescence quantum yields by more than an order of magnitude, and charge-carrier mobility from 46 cm2/(V s) to 56 cm2/(V s). This results in improved solar-cell power conversion efficiency, from 16.4% to 19.3% for the devices employing perovskite films deposited with 20% substitution of PbI2 for PbCl2. Our method presents a scalable, dry, and solvent-free route to reducing nonradiative recombination centers and hence improving the performance of vapor-deposited metal-halide perovskite solar cells.

Optoelectronic properties of mixed iodide-bromide perovskites from first-principles computational modeling and experiment

Journal of Physical Chemistry Letters American Chemical Society 13:18 (2022) 4184-4192

Authors:

Yinan Chen, Silvia G Motti, Robert DJ Oliver, Adam D Wright, Henry J Snaith, Michael B Johnston, Laura M Herz, Marina R Filip

Abstract:

Halogen mixing in lead-halide perovskites is an effective route for tuning the band gap in light emission and multijunction solar cell applications. Here we report the effect of halogen mixing on the optoelectronic properties of lead-halide perovskites from theory and experiment. We applied the virtual crystal approximation within density functional theory, the <i>GW</i> approximation, and the Bethe-Salpeter equation to calculate structural, vibrational, and optoelectronic properties for a series of mixed halide perovskites. We separately perform spectroscopic measurements of these properties and analyze the impact of halogen mixing on quasiparticle band gaps, effective masses, absorption coefficients, charge-carrier mobilities, and exciton binding energies. Our joint theoretical-experimental study demonstrates that iodide-bromide mixed-halide perovskites can be modeled as homovalent alloys, and local structural distortions do not play a significant role for the properties of these mixed species. Our study outlines a general theoretical-experimental framework for future investigations of novel chemically mixed systems.