To clarify the ultrafast temporal interplay of the different photocurrent mechanisms occurring in single InAs-nanowire-based circuits, an on-chip photocurrent pumpprobe spectroscopy based on coplanar striplines was utilized. The data are interpreted in terms of a photo-thermoelectric current and the transport of photogenerated holes to the electrodes as the dominating ultrafast photocurrent contributions. Moreover, it is shown that THz radiation is generated in the optically excited InAs-nanowires, which is interpreted in terms of a dominating photo-Dember effect. The results are relevant for nanowire-based optoelectronic and photovoltaic applications as well as for the design of nanowire-based THz sources.
Three-dimensional topological insulators are a class of Dirac materials, wherein strong spin-orbit coupling leads to two-dimensional surface states. The latter feature spin-momentum locking, i.e., each momentum vector is associated with a spin locked perpendicularly to it in the surface plane. While the principal spin generation capability of topological insulators is well established, comparatively little is known about the interaction of the spins with external stimuli like polarized light. We observe a helical, bias-dependent photoconductance at the lateral edges of topological Bi2Te2Se platelets for perpendicular incidence of light. The same edges exhibit also a finite bias-dependent Kerr angle, indicative of spin accumulation induced by a transversal spin Hall effect in the bulk states of the Bi2Te2Se platelets. A symmetry analysis shows that the helical photoconductance is distinct to common longitudinal photoconductance and photocurrent phenomena, but consistent with optically injected spins being transported in the side facets of the platelets.
Topological insulators
constitute a fascinating class of quantum materials with nontrivial,
gapless states on the surface and insulating bulk states. By revealing
the optoelectronic dynamics in the whole range from femto- to microseconds,
we demonstrate that the long surface lifetime of Bi2Te2Se nanowires allows us to access the surface states by a pulsed
photoconduction scheme and that there is a prevailing bolometric response
of the surface states. The interplay of the surface and bulk states
dynamics on the different time scales gives rise to a surprising physical
property of Bi2Te2Se nanowires: their pulsed
photoconductance changes polarity as a function of laser power. Moreover,
we show that single Bi2Te2Se nanowires can be
used as THz generators for on-chip high-frequency circuits at room
temperature. Our results open the avenue for single Bi2Te2Se nanowires as active modules in optoelectronic high-frequency
and THz circuits.
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