Dr. Suhas Mahesh

Reducing Nonradiative Losses in Perovskite LEDs Through Atomic Layer Deposition of Al2O3 on the Hole-injection Contact

University of Oxford (2023)

Authors:

Emil Dyrvik, Robert Taylor, Alexandra Ramadan, Jonathan Warby, Andreas Lauritzen, Karl-Augustin Zaininger, Henry Snaith, Suhas Mahesh, Melissa McCarthy

Abstract:

Experimental research data collected in laboratories at the Clarendon Laboratory, 2020-2022.

Visualizing macroscopic inhomogeneities in perovskite solar cells

University of Oxford (2022)

Authors:

Akash Dasgupta, Suhas Mahesh, Pietro Caprioglio, Yen-Hung Lin, Karl-Augustin Zaininger, Robert DJ Oliver, Philippe Holzhey, Suer Zhou, Melissa McCarthy, Joel Smith, Maximilian Frenzel, M Greyson Christoforo, James Ball, Bernard Wenger, Henry J Snaith

Abstract:

This contains all data used in the paper: ACS Energy Lett. 2022, 7, 7, 2311–2322, DOI: https://doi.org/10.1021/acsenergylett.2c01094. Data has been sorted into raw and processed, and organised by which figure they appear in. Arrays require Python and the numpy package to load (np.load('filename.npy')). All other data is in text format of some form, easily openable. Some plots require Origin labs to open, but no data in these files are inaccessible from the txt files/ csvs etc.

Crystallographic, optical, and electronic properties of the Cs2AgBi1-xInxBr6 double perovskite: understanding the fundamental photovoltaic efficiency challenges

ACS Energy Letters American Chemical Society 6:3 (2021) 1073-1081

Authors:

Laura Schade, Suhas Mahesh, George Volonakis, Marios Zacharias, Bernard Wenger, Felix Schmidt, Sameer Vajjala Kesava, Dharmalingam Prabhakaran, Mojtaba Abdi-Jalebi, Markus Lenz, Feliciano Giustino, Giulia Longo, Paolo Radaelli, Henry Snaith

Abstract:

We present a crystallographic and optoelectronic study of the double perovskite Cs2AgBi1–xInxBr6. From structural characterization we determine that the indium cation shrinks the lattice and shifts the cubic-to-tetragonal phase transition point to lower temperatures. The absorption onset is shifted to shorter wavelengths upon increasing the indium content, leading to wider band gaps, which we rationalize through first-principles band structure calculations. Despite the unfavorable band gap shift, we observe an enhancement in the steady-state photoluminescence intensity, and n-i-p photovoltaic devices present short-circuit current greater than that of neat Cs2AgBiBr6 devices. In order to evaluate the prospects of this material as a solar absorber, we combine accurate absorption measurements with thermodynamic modeling and identify the fundamental limitations of this system. Provided radiative efficiency can be increased and the choice of charge extraction layers are specifically improved, this material could prove to be a useful wide band gap solar absorber.

A piperidinium salt stabilizes efficient metal-halide perovskite solar cells

Science American Association for the Advancement of Science 369:6499 (2020) 96-102

Authors:

Yen-Hung Lin, Nobuya Sakai, Peimei Da, Jiaying Wu, Harry Sansom, Alexandra Ramadan, Suhas Mahesh, Junliang Liu, Robert Oliver, Jongchul Lim, Lee Aspitarte, Kshama Sharma, Pk Madhu, Anna Morales‐Vilches, Pabitra Nayak, Sai Bai, Feng Gao, Christopher Grovenor, Michael Johnston, John Labram, James Durrant, James Ball, Bernard Wenger, Bernd Stannowski, Henry Snaith

Abstract:

Longevity has been a long-standing concern for hybrid perovskite photovoltaics. We demonstrate high-resilience positive-intrinsic-negative perovskite solar cells by incorporating a piperidiniumbased ionic-compound into the formamidinium-cesium lead-trihalide perovskite absorber. With the band gap tuned to be well suited for perovskite-on-silicon tandem cells, this piperidinium additive enhances the open-circuit voltage and cell efficiency. This additive also retards compositional segregation into impurity phases and pinhole formation in the perovskite absorber layer during aggressive aging. Under full-spectrum simulated sunlight in ambient atmosphere, our Confidential unencapsulated and encapsulated cells retain 80% and 95% of their peak and “post-burn-in” efficiencies for 1010 and 1200 hours at 60 and 85 degree Celsius, respectively. Our analysis reveals detailed degradation routes that contribute to the failure of aged cells.

Revealing the origin of voltage loss in mixed-halide perovskite solar cells

Energy and Environmental Science Royal Society of Chemistry 13 (2019) 258-267

Authors:

Suhas Mahesh, JM Ball, RDJ Oliver, DP McMeekin, P Nayak, MB Johnston, H Snaith

Abstract:

The tunable bandgap of metal-halide perovskites has opened up the possibility of tandem solar cells with over 30% efficiency. Iodide-Bromide (I-Br) mixed-halide perovskites are crucial to achieve the optimum bandgap for such tandems. However, when the Br content is increased to widen the bandgap, cells fail to deliver the expected increase in open-circuit voltage (VOC). This loss in VOC has been attributed to photo-induced halide segregation. Here, we combine Fourier Transform Photocurrent Spectroscopy (FTPS) with detailed balance calculations to quantify the voltage loss expected from the halide segregation, providing a means to quantify the VOC losses arising from the formation of low bandgap iodide-rich phases during halide segregation. Our results indicate that, contrary to popular belief, halide segregation is not the dominant VOC loss mechanism in Br-rich wide bandgap cells. Rather, the loss is dominated by the relatively low initial radiative efficiency of the cells, which arises from both imperfections within the absorber layer, and at the perovskite/charge extraction layer heterojunctions. We thus identify that focussing on maximising the initial radiative efficiency of the mixed-halide films and devices is more important than attempting to suppress halide segeregation. Our results suggest that a VOC of up to 1.33 V is within reach for a 1.77 eV bandgap perovskite, even if halide segregation cannot be supressed