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Heterocyclic and heteropolycyclic moieties in organic hole transport materials for perovskite solar cells: Design, synthesis, and performance

Shakil N. Afraj, Arulmozhi Velusamy, Ming‐Chou Chen, Marwa Abd‐Ellah, Ahmed L. Abdelhady

2025Coordination Chemistry Reviews35 citationsDOIOpen Access PDF

Abstract

This review focuses on the pivotal role of heterocyclic and heteropolycyclic moieties in the development of organic hole-transporting materials (HTMs) for application in perovskite solar cells (PSCs). The escalating demand for sustainable energy sources has heightened interest in PSCs due to their exceptional efficiency and low-cost manufacturing potential. In this review, we highlight the importance of organic-HTMs in PSCs, detailing their innovative molecular design, synthesis, thermal and electrochemical properties, and influence on photovoltaic parameters. The synthesis of heteroatom substituted organic-HTMs from readily available precursors is systematically presented, highlighting key C-N/C-C bond-forming reactions including Buchwald-Hartwig amination, Suzuki, Stille, and Glaser-Hay couplings, as well as Knoevenagel and Horner−Wittig condensations, and Arbuzov reaction. We emphasize the significance of organic synthetic chemistry in designing HTMs with desirable characteristics, such as enhanced solubility, ease of synthesis, simple purification, and characterization by modern analytical techniques. Additionally, the review explores how organic chemistry can enhance critical parameters of HTMs, including energy level alignment, thermal stability, hydrophobicity, hole mobility, and defect passivation ability. Overall, this review describes various organic-HTMs, such as highly π-extended organic molecules, organic passivators, and organic self-assembled monolayers, as emerging HTMs for lead- and tin-based PSCs. To gain insights into the molecular structure, single crystal structures of potential organic-HTMs for PSCs are discussed. In addition, hole-transporting organic passivators playing a role in suppressing the formation of metallic lead (Pb 0 ) on the perovskite surface are highlighted. Future directions of PSC research are discussed, highlighting the potential for further advancements in organic-HTM design and synthesis to drive improvements in PSC performance. Overall, this review is a valuable resource for researchers in the field, offering insights into recent advances and guiding future research endeavors. • Design of π-extended organic molecules, organic passivating agents, and organic self-assembled monolayers as HTMs for PSCs. • Discussion of most significant organic-HTMs for PSCs by highlighting key organic transformations. • Correlation between the structure of organic-HTMs and their impact on physical properties, and PSCs performance. • Role of heteroatoms (O, N, S), halogens (Cl, Br, F), and alkyl chains in HTMsto enhance the efficiency and stability of PSCs. • Exploring future research avenues in PSCs to improve molecular structure of organic-HTMs and boost overall PSC performance.

Topics & Concepts

ChemistryPerovskite (structure)Organic solar cellChemical engineeringNanotechnologyOrganic chemistryPolymerMaterials scienceEngineeringPerovskite Materials and ApplicationsConducting polymers and applicationsOrganic Electronics and Photovoltaics