Highly oriented films of (1010) BaSc 0 . 6 Fe 1 1 . 4 O 1 9 having the magnetic easy axis (crystallographic [0001] axis) in the film plane were deposited by pulsed laser deposition onto a-plane (1120) sapphire (Al 2 O 3 ) substrates. Magnetometry and torque magnetometry measurements showed in-plane permanent magnet (magnetic dipole) behavior below a coercive field value of 450Oe, while high field measurements yielded a uniaxial anisotropy field value of 10kOe. Measurements at temperatures from 123 to 650K showed the uniaxial anisotropy field was insensitive to temperature for T<400K, while the coercive field had a maximum value near 525K before declining to zero at T C =638K. This temperature dependence was modeled by an empirical Brown's-type equation for T=<525K, where the fitting parameters indicated the presence of surprisingly large effective local demagnetizing fields. The film microstructure is inferred to significantly affect the magnetization behavior, and is also presumed to cause significant ferrimagnetic resonance linewidth broadening compared to BaFe 1 2 O 1 9 (0001) films.