Although organic solar cells (OSCs) have delivered an impressive power conversion efficiency (PCE) of over 19?%, most of them demonstrated rather limited stability. So far, there are hardly any effective and universal strategies to improve stability of state‐of‐the‐art OSCs. Herein, we developed a hybrid electron‐transport layer (ETL) in inverted OSCs using ZnO and a new modifying agent (NMA), and significantly improved the stability and PCEs for all the tested devices. In particular, when applied in the D18?:?N3 system, its inverted OSC exhibits so far the highest PCE (18.20?%) among inverted single‐junction OSCs, demonstrating an extrapolated T80 lifetime of 7572?h (equivalent to 5?years under outdoor exposure). This is the first report with T80 over 5000?h among OSCs with over 18?% PCE. Furthermore, a high PCE of 16.12?% can be realized even in a large‐area device (1?cm2). This hybrid ETL strategy provides a strong stimulus for highly prospective commercialization of OSCs.(#br)A new hybrid electron‐transport layer (ETL) ZnO/NMA was developed, when combined with D18?:?N3, the highest power conversion efficiency (18.20?%) among inverted single‐junction organic solar cells was achieved with an operational lifetime of 5?years. The hybrid ETL approach represents an important forward step for the commercial application of OSCs.