TY - JOUR
T1 - Breaking of Coulomb blockade by macrospin-assisted tunneling
AU - Ludwig, Tim
AU - Duine, Rembert A.
PY - 2021/6/1
Y1 - 2021/6/1
N2 - A magnet with precessing magnetization pumps a spin current into adjacent leads. As a special case of this spin pumping, a precessing macrospin (magnetization) can assist electrons in tunneling. In small systems, however, the Coulomb blockade effect can block the transport of electrons. Here, we investigate the competition between macrospin-assisted tunneling and the Coulomb blockade for the simplest system where both effects meet; namely, for a single tunnel junction between a normal metal and a metallic ferromagnet with precessing magnetization. By combining Fermi's golden rule with magnetization dynamics and charging effects, we show that the macrospin-assisted tunneling can soften or even break the Coulomb blockade. The details of these effects - softening and breaking of the Coulomb blockade - depend on the macrospin dynamics. This allows us, for example, to measure the macrospin dynamics via a system's current-voltage characteristics. It also allows us to control a spin current electrically. From a general perspective, our results provide a platform for the interplay between spintronics and electronics on the mesoscopic scale. We expect our work to provide a basis for the study of Coulomb blockade in more complicated spintronic systems.
AB - A magnet with precessing magnetization pumps a spin current into adjacent leads. As a special case of this spin pumping, a precessing macrospin (magnetization) can assist electrons in tunneling. In small systems, however, the Coulomb blockade effect can block the transport of electrons. Here, we investigate the competition between macrospin-assisted tunneling and the Coulomb blockade for the simplest system where both effects meet; namely, for a single tunnel junction between a normal metal and a metallic ferromagnet with precessing magnetization. By combining Fermi's golden rule with magnetization dynamics and charging effects, we show that the macrospin-assisted tunneling can soften or even break the Coulomb blockade. The details of these effects - softening and breaking of the Coulomb blockade - depend on the macrospin dynamics. This allows us, for example, to measure the macrospin dynamics via a system's current-voltage characteristics. It also allows us to control a spin current electrically. From a general perspective, our results provide a platform for the interplay between spintronics and electronics on the mesoscopic scale. We expect our work to provide a basis for the study of Coulomb blockade in more complicated spintronic systems.
UR - https://www.mendeley.com/catalogue/e0cb5022-78af-3f1d-a25e-84b7ffe958a0/
U2 - 10.1103/PhysRevB.103.224406
DO - 10.1103/PhysRevB.103.224406
M3 - Article
SN - 0163-1829
VL - 103
SP - 1
EP - 7
JO - Physical Review B
JF - Physical Review B
IS - 22
M1 - 224406
ER -