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Elucidating the Role of Ligand Engineering on Local and Macroscopic Charge‐Carrier Transport in NaBiS<sub>2</sub> Nanocrystal Thin Films

Yi‐Teng Huang, Markus Schleuning, Hannes Hempel, Youcheng Zhang, Marin Rusu, Thomas Unold, Artem Musiienko, Orestis Karalis, Nora Jung, Szymon J. Zelewski, Andrew J. Britton, Natalie Ngoh, Weixin Song, Louise C. Hirst, Henning Sirringhaus, Samuel D. Stranks, Akshay Rao, Igal Levine, Robert L. Z. Hoye

2024Advanced Functional Materials13 citationsDOIOpen Access PDF

Abstract

Abstract Ternary chalcogenides have emerged as potential candidates for ultrathin photovoltaics, and NaBiS 2 nanocrystals (NCs) have gained appeal because of their months‐long phase‐stability in air, high absorption coefficients &gt;10 5 cm −1 , and a pseudo‐direct bandgap of 1.4 eV. However, previous investigations into NaBiS 2 NCs used long‐chain organic ligands separating individual NCs during synthesis, which severely limits macroscopic charge‐carrier transport. In this work, these long‐chain ligands are exchanged for short iodide‐based ligands, allowing to understand the macroscopic charge‐carrier transport properties of NaBiS 2 and evaluate its photovoltaic potential in more depth. It is found that ligand exchange results in simultaneous improvements in intra‐NC (microscopic) and inter‐NC (macroscopic) mobilities, while charge‐carrier localization still takes place, which places a fundamental limit on the transport lengths achievable. Despite this limitation, the high absorption coefficients enable ultrathin (55 nm thick) solar absorbers to be used in photovoltaic devices, which have peak external quantum efficiencies &gt; 50%. In addition, temperature‐dependent transient current measurements uncover a small activation energy barrier of 88 meV for ion migration, which accounts for the strongly hysteretic behavior of NaBiS 2 photovoltaic devices. This work not only reveals how the charge‐carrier transport properties of NaBiS 2 NCs over several length and time scales are influenced by ligand engineering, but also unveils the facile ionic transport in this material, which limits the potential of NaBiS 2 in photovoltaics. On the other hand, the discovery shows that there are opportunities to use this material in memristors, electrolytes, and other applications requiring ionic conduction.

Topics & Concepts

Materials sciencePhotovoltaicsChemical physicsCharge carrierCharge (physics)Band gapPhotovoltaic systemNanotechnologyAbsorption (acoustics)Ionic bondingOptoelectronicsIonChemistryPhysicsElectrical engineeringEngineeringOrganic chemistryQuantum mechanicsComposite materialPerovskite Materials and ApplicationsQuantum Dots Synthesis And PropertiesChalcogenide Semiconductor Thin Films
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