2D matrix engineering for homogeneous quantum dot coupling in photovoltaic solids

Colloidal quantum dots (CQDs) are promising photovoltaic (PV) materials because of their widely tunable absorption spectrum controlled by nanocrystal size(1,2). Their bandgap tunability allows not only the optimization of single-junction cells, but also the fabrication of multijunction cells that complement perovskites and silicon(3). Advances in surface passivation(2,4-7), combined with advances in device structures8, have contributed to certified power conversion efficiencies (PCEs) that rose to 11% in 2016(9). Further gains in performance are available if the thickness of the devices can be increased to maximize the light harvesting at a high fill factor (FF). However, at present the active layer thickness is limited to similar to 300 nm by the concomitant photocarrier diffusion length. To date, CQD devices thicker than this typically exhibit decreases in shortcircuit current (J(SC)) and open-circuit voltage (V-OC), as seen in previous reports(3,9-11). Here, we report a matrix engineering strategy for CQD solids that significantly enhances the photocarrier diffusion length. We find that a hybrid inorganic-amine coordinating complex enables us to generate a high-quality two-dimensionally (2D) confined inorganic matrix that programmes internanoparticle spacing at the atomic scale. This strategy enables the reduction of structural and energetic disorder in the solid and concurrent improvements in the CQD packing density and uniformity. Consequently, planar devices with a nearly doubled active layer thicknesses (similar to 600 nm) and record values of J(SC) (32 mA cm(-2)) are fabricated. The V-OC improved as the current was increased. We demonstrate CQD solar cells with a certified record efficiency of 12%.