We study the electronic and magneto-transport properties of multiferroic oxide-based structures and explore their
potential for spintronic applications. In particular, we point out the possibility of using the two dimensional
electron gas (2DEG) formed at the interface of helimagnetic oxides as a spin-field-effect transistor and a flash
memory device. The operation of this device relies on the fact that the topology of the multiferroic oxide local
magnetic moments results in a resonant momentum-dependent effective spin-orbit interaction acting on 2DEG.
The spin polarization dephasing is strongly suppressed which is crucial for functionality. The effective spin-orbit
interaction and the carrier spin precession phase depend linearly on the magnetic spiral helicity which, due to the
magnetoelectric coupling, is electrically controllable. We also consider helical multiferroic tunnel junctions with
a normal metallic layer as the bottom electrode and a ferromagnetic layer as the other electrode. It is shown
that the tunnel-magneto-resistance is spatially dependent and is controllable via an external electric field.
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