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Magnetic electron collimation in three-dimensional semi-metals

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arxiv 2001.03273 v1 pith:CEF5GMGG submitted 2020-01-10 cond-mat.mtrl-sci cond-mat.mes-hall

Magnetic electron collimation in three-dimensional semi-metals

classification cond-mat.mtrl-sci cond-mat.mes-hall
keywords currentfieldelectronmagneticbeamssemi-metalscontactscontrolled
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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While electrons moving perpendicular to a magnetic field are confined to cyclotron orbits, they can move freely parallel to the field. This simple fact leads to complex current flow in clean, low carrier density semi-metals, such as long-ranged current jets forming along the magnetic field when currents pass through point-like constrictions. Occurring accidentally at imperfect current injection contacts, the phenomenon of "current jetting" plagues the research of longitudinal magneto-resistance which is particularly important in topological conductors. Here we demonstrate the controlled generation of tightly focused electron beams in a new class of micro-devices machined from crystals of the Dirac semi-metal Cd3As2. The current beams can be guided by tilting a magnetic field and their range tuned by the field strength. Finite element simulations quantitatively capture the voltage induced at faraway contacts when the beams are steered towards them, supporting the picture of controlled electron jets. These experiments demonstrate the first direct control over the highly nonlocal signal propagation unique to 3D semi-metals in the current jetting regime, and may lead to novel applications akin to electron optics in free space.

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