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P. Toson, W. Wallisch, A. Asali, J. Fidler:
"Modelling of Packed Co Nanorods for Hard Magnetic Applications";
EPJ Web of Conferences, 75 (jems 2013 - Joint European Magnetic Symposia (2014), 03002.

We present a numerical algorithm based on the bullet physics library to generate densely packed
(39% - 41%) structures of high-aspect-ratio nanorods for finite element micromagnetic simulations. The
coercivities μ0Hc of the corresponding Cobalt nanorod structures vary between 0.50T and 0.67T, depending on
the overall orientation of nanorods, which is in good agreement with experimental results. The simulations
make it possible to estimate the coercivity loss due to incoherent reversal processes (27%) as well as the gain
due to shape anisotropy (59%). Our calculations show permanent magnets consisting of packed Co nanorods
with an energy density product (BH)max of 83kJ/m³. We estimate that this value can be increased to 103kJ/m³
by increasing the packing density from 40% to 45%. Another way to optimize (BH)max is the usage of novel
materials. By varying the anisotropy constant K1 and the saturation polarisation JS we found lower limits for
these parameters to reach a certain energy density product. To increase (BH)max to 160 kJ/m³, K1 and JS have to
be in the order of 450kJ/m³ and 2.25T, respectively. The thermal stability of this approach was verified by
elastic band calculations. Cobalt nanorods with a diameter of 10nm and a height of 50nm are thermally stable
at room temperature, but problematic at 900K. Doubling the nanorods' height to 100nm increases that limit
considerably.

http://dx.doi.org/10.1051/epjconf/20147503002