Esther Hung

Understanding the degradation of methylenediammonium and its role in phase-stabilizing formamidinium lead triiodide

Journal of the American Chemical Society American Chemical Society 145:18 (2023) 10275-10284

Authors:

Elisabeth A Duijnstee, Benjamin M Gallant, Philippe Holzhey, Dominik J Kubicki, Silvia Collavini, Bernd K Sturdza, Robin J Nicholas, Harry C Sansom, Joel Smith, Matthias J Gutmann, Santanu Saha, Murali Gedda, Mohamad I Nugraha, Manuel Kober-Czerny, Chelsea Xia, Adam D Wright, Yen-Hung Lin, Alexandra J Ramadan, Andrew Matzen, Esther Y-H Hung, Seongrok Seo, Suer Zhou, Jongchul Lim, Thomas D Anthopoulos, Marina R Filip, Michael B Johnston, Juan Luis Delgado, Henry J Snaith

Abstract:

Formamidinium lead triiodide (FAPbI₃) is the leading candidate for single-junction metal–halide perovskite photovoltaics, despite the metastability of this phase. To enhance its ambient-phase stability and produce world-record photovoltaic efficiencies, methylenediammonium dichloride (MDACl₂) has been used as an additive in FAPbI₃. MDA²⁺ has been reported as incorporated into the perovskite lattice alongside Cl^–. However, the precise function and role of MDA²⁺ remain uncertain. Here, we grow FAPbI₃ single crystals from a solution containing MDACl₂ (FAPbI₃-M). We demonstrate that FAPbI₃-M crystals are stable against transformation to the photoinactive δ-phase for more than one year under ambient conditions. Critically, we reveal that MDA²⁺ is not the direct cause of the enhanced material stability. Instead, MDA²⁺ degrades rapidly to produce ammonium and methaniminium, which subsequently oligomerizes to yield hexamethylenetetramine (HMTA). FAPbI₃ crystals grown from a solution containing HMTA (FAPbI₃-H) replicate the enhanced α-phase stability of FAPbI₃-M. However, we further determine that HMTA is unstable in the perovskite precursor solution, where reaction with FA⁺ is possible, leading instead to the formation of tetrahydrotriazinium (THTZ-H⁺). By a combination of liquid- and solid-state NMR techniques, we show that THTZ-H⁺ is selectively incorporated into the bulk of both FAPbI₃-M and FAPbI₃-H at ∼0.5 mol % and infer that this addition is responsible for the improved α-phase stability.

A green solvent enables precursor phase engineering of stable formamidinium lead triiodide perovskite solar cells

Nature Communications Nature Research 15:1 (2024) 10110

Authors:

Benjamin M Gallant, Philippe Holzhey, Joel A Smith, Saqlain Choudhary, Karim A Elmestekawy, Pietro Caprioglio, Igal Levine, Alexandra A Sheader, Esther Y-H Hung, Fengning Yang, Daniel TW Toolan, Rachel C Kilbride, Karl-Augustin Zaininger, James M Ball, M Greyson Christoforo, Nakita K Noel, Laura M Herz, Dominik J Kubicki, Henry J Snaith

Abstract:

Perovskite solar cells (PSCs) offer an efficient, inexpensive alternative to current photovoltaic technologies, with the potential for manufacture via high-throughput coating methods. However, challenges for commercial-scale solution-processing of metal-halide perovskites include the use of harmful solvents, the expense of maintaining controlled atmospheric conditions, and the inherent instabilities of PSCs under operation. Here, we address these challenges by introducing a high volatility, low toxicity, biorenewable solvent system to fabricate a range of 2D perovskites, which we use as highly effective precursor phases for subsequent transformation to α-formamidinium lead triiodide (α-FAPbI3), fully processed under ambient conditions. PSCs utilising our α-FAPbI3 reproducibly show remarkable stability under illumination and elevated temperature (ISOS-L-2) and “damp heat” (ISOS-D-3) stressing, surpassing other state-of-the-art perovskite compositions. We determine that this enhancement is a consequence of the 2D precursor phase crystallisation route, which simultaneously avoids retention of residual low-volatility solvents (such as DMF and DMSO) and reduces the rate of degradation of FA+ in the material. Our findings highlight both the critical role of the initial crystallisation process in determining the operational stability of perovskite materials, and that neat FA+-based perovskites can be competitively stable despite the inherent metastability of the α-phase.

Fullerene derivative integration controls morphological behaviour and recombination losses in non-fullerene acceptor-based organic solar cells

Materials Horizons Royal Society of Chemistry (2025)

Authors:

Apostolos Panagiotopoulos, Kyriakos Almpanidis, Esther Y-H Hung, Nikolaos Lempesis, Weidong Xu, George Perrakis, Sandra Jenatsch, Levon Abelian, Stoichko Dimitrov, Dimitar Kutsarov, Ehsan Rezaee, Benjamin M Gallant, Vlad Stolojan, Konstantinos Petridis, Samuel D Stranks, Henry J Snaith, George Kakavelakis, S Ravi P Silva

Abstract:

The complex and varied relationship found in intermolecular interactions within the photo-active layers plays a decisive role in determining the photovoltaic energy conversion and overall device performance of organic solar cells (OSCs). Among different approaches, the ternary blend strategy serves as an effective technique to control the morphology within the active layer in OSCs. In this work, PM6:L8-BO is used as the main host system (binary) while the fullerene molecules PC61BM and PCBC6 are introduced to form ternary OSCs. The results highlight the important role of fullerenes in enhancing the performance of binary non-fullerene acceptor-based cells by suppressing trap-assisted recombination and optimizing the active layer morphology. The improved film phase microstructure, enabled by fullerene derivatives with higher lowest unoccupied molecular orbital (LUMO) energy levels in comparison to the host acceptor (L8-BO), facilitates more efficient charge collection and reduced non-radiative recombination. This results in an increase in the fill factor (FF) and open circuit voltage (Voc) in the ternary OSCs. Consequently, power conversion efficiencies (PCEs) of binary OSCs were increased from 17.28% to 18.10% and 18.38% for the PC61BM- and PCBC6-based ternary OSCs, respectively. Furthermore, the addition of the fullerene molecules in the active layer provided the devices with enhanced long-term photo and thermal stability. The ternary OSCs demonstrated degradation pathways distinct from those of binary cells (ISOS-L1-I and ISOS-D2-I protocols), as identified through in situ ultraviolet-visible (UV-Vis) absorption and Raman spectroscopy. Molecular dynamics (MD) simulations, for the first time, reveal the significant role of fullerene molecules as morphology regulators in non-fullerene acceptor (NFA)-based systems. Their presence ensures improved dispersion of blend components and promotes more uniform and isotropic thermal and mechanical behaviour. Finally, mini-modules with active areas of 3.8 cm2 were fabricated, achieving PCEs of 12.90%, 13.32%, and 13.70% for the binary and ternary cells using PC61BM-and PCBC6-based ternary cells, respectively. Our results demonstrate that regulation of the morphology of the photo-active layer in OSCs through fullerene incorporation reduces the non-radiative energy loss pathways, enabling high-efficiency, stable and scalable OSCs.

Tailoring a Lead-Free Organic–Inorganic Halobismuthate for Large Piezoelectric Effect

Journal of the American Chemical Society American Chemical Society 147:49 (2025) 45366-45376

Authors:

Esther YH Hung, Benjamin M Gallant, Robert Harniman, Jakob Möbs, Santanu Saha, Khaled Kaja, Charles Godfrey, Shrestha Banerjee, Nikolaos Famakidis, Harish Bhaskaran, Marina R Filip, Paolo Radaelli, Nakita K Noel, Dominik J Kubicki, Harry C Sansom, Henry J Snaith

Abstract:

Molecular piezoelectrics are a potentially disruptive technology, enabling a new generation of self-powered electronics that are flexible, high performing, and inherently low in toxicity. Although significant efforts have been made toward understanding their structural design by targeted manipulation of phase transition behavior, the resulting achievable piezoresponse has remained limited. In this work, we use a low-symmetry, zero-dimensional (0D) inorganic framework alongside a carefully selected ‘quasi-spherical’ organic cation to manipulate organic–inorganic interactions and thus form the hybrid, piezoelectric material [(CH3)3NCH2I]3Bi2I9. Using variable–temperature single crystal X-ray diffraction and solid-state nuclear magnetic resonance spectroscopy, we demonstrate that this material simultaneously exhibits an order–disorder and displacive symmetry-breaking phase transition. This phase transition is mediated by halogen bonding between the organic and inorganic frameworks and results in a large piezoelectric response, d 33 = 161.5 pm/V. This value represents a 4-fold improvement on previously reported halobismuthate piezoelectrics and is comparable to those of commercial inorganic piezoelectrics, thus offering a new pathway toward low-cost, low-toxicity mechanical energy harvesting and actuating devices.

Exposing binding-favourable facets of perovskites for tandem solar cells

Energy & Environmental Science Royal Society of Chemistry 18 (2025) 7680-7694

Authors:

Junke Wang, Shuaifeng Hu, Zehua Chen, Zhongcheng Yuan, Pei Zhao, Akash Dasgupta, Fengning Yang, Jin Yao, Minh Anh Truong, Gunnar Kusch, Esther Hung, Nick Schipper, Laura Bellini, Guus Aalbers, Zonghao Liu, Rachel Oliver, Atsushi Wakamiya, René Janssen, Henry Snaith

Abstract:

Improved understanding of heterojunction interfaces has enabled multijunction photovoltaic devices to achieve power conversion efficiencies that exceed the detailed-balance limit for single-junctions. For wide-bandgap perovskites, however, the pronounced energy loss across the heterojunctions of the active and charge transport layers impedes multijunction devices from reaching their full efficiency potential. Here we find that for polycrystalline perovskite films with mixed-halide compositions, the crystal termination—a factor influencing the reactivity and density of surface sites—plays a crucial role in interfacial passivation for wide-bandgap perovskites. We demonstrate that by templating the growth of polycrystalline perovskite films toward a preferred (100) facet, we can reduce the density of deep-level trap states and enhance the binding of modification ligands. This leads to a much-improved heterojunction interface, resulting in open-circuit voltages of 1.38 V for 1.77-eV single-junction perovskite solar cells. In addition, monolithic all-perovskite double-junction solar cells achieve open-circuit voltage values of up to 2.22 V, with maximum power point tracking efficiencies reaching 28.6% and 27.7% at 0.25 and 1.0 cm2 cell areas, respectively, along with improved operational and thermal stability at 85 °C. This work provides universally applicable insights into the crystalline facet-favourable surface modification of perovskite films, advancing their performance in optoelectronic applications.