Chromium telluride (Cr(1+δ)Te2) thin films of various δ were prepared using a hybrid pulsed laser deposition technique by varying the flux rate of a Te-molecular beam source. We found that the thickness and nanocrystalline quality of the films increased with the Te-flux. All three films prepared showed hexagonal layering with the same out-of-plane lattice constant. Increasing the Te-flux rate stabilized the CrTe, Cr2Te3, and CrTe2 phases of the telluride, and they showed different magnetic transition temperatures (TC) from film to film, corresponding to their composition. The tellurides show anisotropic magnetoresistance (AMR) and a metal-to-insulator transition (MIT) at the vicinity of their respective TCs, with the highest TC of 324 K unveiled by Cr2Te3. These stoichiometry-controlled room-temperature ferromagnetic air-stable 2D materials prepared using the hybrid deposition technique can significantly advance further development of 2D materials for magnetic device applications.