We have studied the thickness and angular dependence of the magnetocurrent of hot electrons in a magnetic tunnel transistor (MTT) with crossed magnetic anisotropies. In a first step, we show that the magnetocurrent increases with ferromagnetic layer thickness as for MTTs with collinear magnetic configurations. The maximum magnetocurrent value is obtained to be 85%, which is close to the theoretical maximum value of 100% for MTTs with crossed magnetic configurations. In a second step, we demonstrate that we are able to reproduce both current vs field direction and current vs field intensity measurements in a framework taking into account a reduced number of magnetic parameters and a simple cosine dependence of the hot-electron current on the angle between magnetizations.
Magnetic biochips based on switchable magnetic nano-traps were developed and optimized so as to enable faster bio-assays via a reduction of steps and the efficient capture of analytes in a sample test solution. Nano-traps are based on snake shaped magnetic nanowires made by microelectronic technics from a thin magnetic layer. This optimized design ensures high local fields when the trap is activated and reduced stray fields when deactivated with respect to previous designs. Our proof-of-concept model consists to determine the anchorage of synthetic peptides in a bilayer enveloping magnetic beads by revealing their presence via fluorescently labeled immunoglobulins elicited against the native proteins of the said exposed peptides.
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