Abstract

Abstract A route for the fabrication of magnetic nanotubes is established by combining glancing angle deposition (GLAD) and atomic layer deposition (ALD). In a first step, arrays of inclined or upright columnar Si structures are deposited using a glancing angle ion beam sputter technique. In a second step, these columns are covered with Fe 2 O 3 by means of ALD, thus fabricating tubular structures with well defined wall thicknesses that envelop the Si columns. Subsequent reduction in Ar/H 2 atmosphere converts the Fe 2 O 3 tubes to ferrimagnetic Fe 3 O 4 tubes. Using superconducting quantum interference magnetometry, the orientation dependence of the coercive field is extracted from magnetization isotherms, recorded on as‐fabricated samples oriented at various angles with respect to the magnetic field. We find an angular dependence in the variation of the coercive field, which is related to the inclination angle of the columns. magnified image Cross‐sectional scanning electron micrograph of a columnar zigzag Si structure.