Asymmetric tandem organic photovoltaic cells with hybrid planar-mixed molecular heterojunctions

We demonstrate high-efficiency organic photovoltaic cells by stacking two hybrid planar-mixed molecular heterojunction cells in series. Absorption of incident light is maximized by locating the subcell tuned to absorb long-wavelength light nearest to the transparent anode, and tuning the second subcell closest to the reflecting metal cathode to preferentially absorb short-wavelength solar energy. Using the donor, copper phthalocyanine, and the acceptor, C 60 , we achieve a maximum power conversion efficiency of η P = ( 5.7 ± 0.3 ) % under 1 sun simulated AM1.5G solar illumination. An open-circuit voltage of V OC ⩽ 1.2 V is obtained, doubling that of a single cell. Analytical models suggest that power conversion efficiencies exceeding 6.5% can be obtained by this architecture.