Photoredox‐catalyzed methylcyclobutanations of alkylboronic esters are described. The reactions proceed through single‐electron transfer induced deboronative radical addition to an electron‐deficient alkene followed by single‐electron reduction and polar 4‐exo‐tet cyclization with a pendant alkyl halide. Key to the success of the methodology was the use of easily oxidizable arylboronate complexes. Structurally diverse cyclobutanes are shown to be conveniently prepared from readily available alkylboronic esters and a range of haloalkyl alkenes. The mild reactions display excellent functional group tolerance, and the radical addition‐polar cyclization cascade also enables the synthesis of 3‐, 5‐, 6‐, and 7‐membered rings. Arylboronate complexes formed from alkylboronic esters and phenyllithium were found to undergo facile single‐electron oxidation to form alkyl radicals. The novel use of these complexes as radical precursors enabled the development of a photoredox‐catalyzed cyclobutane synthesis proceeding through a radical‐polar crossover mechanism.