Semitransparent Organic Solar Cells with Homogeneous Transmission and Colorful Reflection Enabled by an ITO‐Free Microcavity Architecture

Semitransparent organic photovoltaics (ST‐OPVs), owing to the merits of high power generation, thermal insulation, and aesthetic features, have become a promising candidate for intellectual building‐ integrated photovoltaic windows. However, the traditional optical evaluation only focuses on the transmission properties and ignores the reflection behaviors. And the lack of quantitative descriptions for array appearance hinders implementation of ST‐OPV based large‐area modules. To tackle with these issues, an indium tin oxide (ITO)‐free optical microcavity architecture into ST‐OPVs for achieving high homogeneity in transmittance with controllable reflective appearances through tunning the thickness of individual component layers is introduced. A set of parameters based on optical characteristics of sub‐units to provide a quantitative description for the transmittance brightness, transmissive and reflective color purity, and versatility of optical arrays, is further proposed. The optical simulations reveal that reflection modulation from blue to red colors can be realized for devices based on various bulk‐heterojunction material systems through regulating the thickness of active layers and antireflection coatings. This work offers a viable design strategy for ST‐OPVs toward applications in next‐generation smart photovoltaic windows. Here, an indium tin oxide‐free optical microcavity architecture into semitransparent organic photovoltaics for achieving high transmittance homogeneity with controllable reflection through tunning the individual component layer thickness is introduced. And six parameters based on optical characteristics of subunits to provide a quantitative description for the transmittance brightness, transmissive and reflective color purity, and versatility of optical arrays, is proposed.