Litcius/Paper detail

Near-Unity Broadband Quantum Efficiency Enabled by Colloidal Quantum Dot/Mixed-Organic Heterojunction

Yujin Jung, Hyeyoung Shin, Se‐Woong Baek, Truong Ba Tai, Benjamin Scheffel, Olivier Ouellette, Margherita Biondi, Sjoerd Hoogland, F. Pelayo Garcı́a de Arquer, Edward H. Sargent

2023ACS Energy Letters21 citationsDOI

Abstract

Solution-processed semiconducting materials are promising for realizing high-performance, low-cost, and flexible energy conversion devices. In particular, hybrid structures comprising colloidal quantum dots (CQDs) and organic molecules have been proposed to achieve broadband absorption across the visible-to-infrared solar spectrum. However, the photophysical mismatch present at CQD/organic interfaces limits charge extraction, resulting in low power conversion efficiency (PCE). In this study, we sought to overcome this photophysical mismatch, addressing the CQD/organic interface using a library of surface ligands with different functions. We established, using both experiments and theoretical calculations, that thiol termination of the CQD surface reduced the interfacial barrier, resulting in a 4-fold higher charge transfer efficiency at the maximum power point bias. The CQD/mixed-organic heterojunction solar cells exhibit a record photocurrent density of 33.3 mA/cm 2 and near-unity broadband quantum efficiency up to 1100 nm, demonstrating the potential of these devices to harvest infrared solar photons in all-solution-processed tandem devices.

Topics & Concepts

PhotocurrentHeterojunctionQuantum dotOptoelectronicsMaterials scienceEnergy conversion efficiencyQuantum efficiencyOrganic solar cellNanotechnologyPolymerComposite materialQuantum Dots Synthesis And PropertiesPerovskite Materials and ApplicationsChalcogenide Semiconductor Thin Films