Prof Henry Snaith FRS

Charge Extraction Multilayers Enable Positive-Intrinsic-Negative Perovskite Solar Cells with Carbon Electrodes.

ACS energy letters 10:6 (2025) 2736-2742

Authors:

Tino Lukas, Seongrok Seo, Philippe Holzhey, Katherine Stewart, Charlie Henderson, Lukas Wagner, David Beynon, Trystan M Watson, Ji-Seon Kim, Markus Kohlstädt, Henry J Snaith

Abstract:

Perovskite solar cells achieve high power conversion efficiencies but usually rely on vacuum-deposited metallic contacts, leading to high material costs for noble metals and stability issues for more reactive metals. Carbon-based materials offer a cost-effective and potentially more stable alternative. The vast majority of carbon-electrode PSCs use the negative-intrinsic-positive (n-i-p) or "hole-transport-layer-free" architectures. Here, we present a systematic study to assess the compatibility of "inverted", p-i-n configuration PSC contact layers with carbon top electrodes. We identify incompatibilities between common electron transport layers and the carbon electrode deposition process and previously unobserved semiconducting properties in carbon electrodes with unique implications for charge extraction and electronic behavior. To overcome these issues, we introduce a double-layer atomic layer deposited tin oxide (SnO₂) and Poly-(2,3-dihydrothieno-1,4-dioxin)-poly-(styrenesulfonate) (PEDOT:PSS), yielding up to 16.1% PCE and a retained 94% performance after 500 h of outdoor aging. The study is a crucial step forward for printable, metal-electrode-free, and evaporation-free perovskite PV technologies.

Diamine Surface Passivation and Postannealing Enhance the Performance of Silicon-Perovskite Tandem Solar Cells.

ACS applied materials & interfaces (2025)

Authors:

Margherita Taddei, Hannah Contreras, Hai-Nam Doan, Declan P McCarthy, Seongrok Seo, Robert JE Westbrook, Daniel J Graham, Kunal Datta, Perrine Carroy, Delfina Muñoz, Juan-Pablo Correa-Baena, Stephen Barlow, Seth R Marder, Joel A Smith, Henry J Snaith, David S Ginger

Abstract:

We show that the use of 1,3-diaminopropane (DAP) as a chemical modifier at the perovskite/electron-transport layer (ETL) interface enhances the power conversion efficiency (PCE) of 1.7 eV band gap mixed-halide perovskite containing formamidinium and Cs single-junction cells, primarily by increasing the open-circuit voltage (V_OC) from 1.06 to 1.15 V. We find that adding a postprocessing annealing step after C60 evaporation further improves device performance. Specifically, the fill factor (FF) increases by 20% in the DAP + postannealing devices compared to the control. Using hyperspectral photoluminescence microscopy, we demonstrate that annealing helps improve compositional homogeneity at the electron-transport layer (ETL) and hole-transport layer (HTL) interfaces of the solar cell, which prevents detrimental band gap pinning in the devices and improves C₆₀ adhesion. Using time-of-flight secondary ion mass spectrometry, we show that DAP reacts with formamidinium (FA⁺) present at the surface of the perovskite structure to form a larger molecular cation, 1,4,5,6-tetrahydropyrimidinium (THP⁺), which remains at the interface. Combining the use of DAP and annealing the C₆₀ interface, we fabricate Si-perovskite tandems with a PCE of 25.29%, compared to 23.26% for control devices. Our study underscores the critical role of the chemical reactivity of diamines at the surface and the thermal postprocessing of the C₆₀/Lewis-base passivator interface in minimizing device losses and enhancing solar-cell performance of wide-band-gap mixed-cation mixed-halide perovskites for tandem applications.

Mercapto-functionalized scaffold improves perovskite buried interfaces for tandem photovoltaics

Nature Communications Springer Science and Business Media LLC 16:1 (2025) 4917

Authors:

Jianan Wang, Shuaifeng Hu, He Zhu, Sanwan Liu, Zhongyong Zhang, Rui Chen, Junke Wang, Chenyang Shi, Jiaqi Zhang, Wentao Liu, Xia Lei, Bin Liu, Yongyan Pan, Fumeng Ren, Hasan Raza, Qisen Zhou, Sibo Li, Longbin Qiu, Guanhaojie Zheng, Xiaojun Qin, Zhiguo Zhao, Shuang Yang, Neng Li, Jingbai Li, Atsushi Wakamiya, Zonghao Liu, Henry J Snaith, Wei Chen

Influence of Interfacial Reactions on Perovskite Optoelectronic Devices

small methods Wiley (2025) 2500438

Authors:

Zhongcheng Yuan, Sai Bai, Feng Gao, Henry J Snaith

Abstract:

Interfacial materials tend to alter the crystallization, films growth and defect formation process of the as‐deposited perovskites, which has been a critical and fundamental factor in determining the efficiency and operational stability of perovskite‐based optoelectronic devices. This review explores the underlying mechanism of interfacial reactions, which can either result in degradations or be beneficial. The influence of interfacial reactions, mainly interface‐induced deprotonation of organic cations and amidation processes, are discussed in relation to their impact on perovskite film growth and ensuing optoelectronic device performance. It is further proposed strategies to regulate these reactions and mitigate their negative effects to achieve high performance optoelectronic devices.

Interfacial Energetics Reversal Strategy for Efficient Perovskite Solar Cells.

Advanced materials (Deerfield Beach, Fla.) Wiley (2025) e2503110

Authors:

Sheng Jiang, Shaobing Xiong, Zhongcheng Yuan, Yafang Li, Xiaomeng You, Hongbo Wu, Menghui Jia, Zhennan Lin, Zaifei Ma, Yuning Wu, Yefeng Yao, Xianjie Liu, Junhao Chu, Zhenrong Sun, Mats Fahlman, Henry J Snaith, Qinye Bao

Abstract:

Reducing heterointerface nonradiative recombination is a key challenge for realizing highly efficient perovskite solar cells (PSCs). Motivated by this, a facile strategy is developed via interfacial energetics reversal to functionalize perovskite heterointerface. A surfactant molecule, trichloro[3-(pentafluorophenyl)propyl]silane (TPFS) reverses perovskite surface energetics from intrinsic n-type to p-type, evidently demonstrated by ultraviolet and inverse photoelectron spectroscopies. The reconstructed perovskite surface energetics match well with the upper deposited hole transport layer, realizing an exquisite energy level alignment for accelerating hole extraction across the heterointerface. Meanwhile, TPFS further diminishes surface defect density. As a result, this cooperative strategy leads to greatly minimized nonradiative recombination. PSCs achieve an impressive power conversion efficiency of 25.9% with excellent reproducibility, and a nonradiative recombination-induced qV_oc loss of only 57 meV, which is the smallest reported to date in n-i-p structured PSCs.