Magnetic properties of Co nanocolumns fabricated by oblique-angle deposition.

The magnetic properties of columnar Co films on SiO[sub 2] substrates fabricated by oblique-angle incident thermal evaporation at room temperature were systematically examined by multiple techniques, including magnetic force microscopy (MFM), magneto-optical Kerr effect (MOKE), and scanning electron microscopy (SEM). Films with thickness ranging from 50 to 500 nm were deposited at the incident angles θ (with respect to substrate normal) from 0° to 85°. For films with thickness of ∼500 nm, the SEM shows the column tilt angle β increases as the θ angle increases and β < θ. The MFM images show that for 55° < θ < 75°, stripe domains are formed and are nearly parallel to the direction of incident vapor beam. The hysteresis loops obtained from MaKE show that along the direction perpendicular to the incident vapor beam the coercivity H[sub c] stays almost constant for all θ angles and the squareness decreases as the θ increases. This is in contrast to the increase of H[sub c] and the increase of squareness in the direction parallel to the incident vapor beam for θ > 60°. The result implies that for θ > 60°, the axis parallel to the incident beam behaves more like the in-plane easy axis. These magnetic anisotropies are correlated to the angular-dependent columnar structure of Co films. [ABSTRACT FROM AUTHOR]