Linear polyacenes and their derivatives are well-recognized organic semiconductors because of their fascinating singlet fission (SF) property. However, higher polyacenes (e.g., pentacene and hexacene) suffer from poor chemical stability. Herein, we present photophysics of a nonlinearly fused analogue of heptacene, namely, dibenzo[a,l]pentacene in monomer and thin film forms. Nonlinear fusion of benzene rings at two sides of the linear pentacene core results in a weaker and blue-shifted absorption. Interestingly, thin film formation introduces a substantial red shift of absorption along with ∼5 times enhancement in absorption strength due to the cooperative intermolecular interaction in the solid state. Femtosecond and nanosecond pump–probe experiments reveal that the thin film of DBPn undergoes fast singlet fission (a time constant of ∼5.2 ps) to the triplet pair state, followed by dissociation to long-lived free triplets in hundreds of picoseconds with near-unity SF yield. Endowed with higher solubility and better photostability as compared to pentacene, observation of fast and efficient singlet fission makes DBPn a potential candidate for organic photovoltaic applications.