Hard-magnetic L1₀ phase FePt has been demonstrated as a promising candidate for future nanomagnetic applications, especially magnetic recording at areal densities approaching 10 Tb/in². Realization of FePt's potential in recording media requires control of grain size and intergranular exchange interactions in films with high degrees of L1₀ order and (001) crystalline texture, including high perpendicular magnetic anisotropy. Furthermore, a write-assist mechanism must be employed to overcome the high coercivity of L1₀ FePt nanograins. The research described in this dissertation examines potential solutions to the aforementioned problems. Specifically, a nonepitaxial method of fabricating highly (001) textured thin films is investigated by careful tuning of the as-deposited structure. Such highly textured films could be useful as a template for bit-patterned media. Secondly, control of grain size and intergranular magnetic interactions is demonstrated using non-magnetic additions of Al₂O₃, C, and Au. Finally, large reductions in the coercivity of high anisotropy, epitaxially grown L1₀ FePt islands are achieved in an exchange-coupled composite system by adding an exchange coupled layer of FePt:SiO₂ with moderate anisotropy. The results show promise for the implementation of L1₀ FePt in future magnetic recording media and other nanomagnetic applications.