8 research outputs found
Broadband microwave spectroscopy of semiconductor nanowire-based Cooper-pair transistors
The Cooper-pair transistor (CPT), a small superconducting island enclosed
between two Josephson weak links, is the atomic building block of various
superconducting quantum circuits. Utilizing gate-tunable semiconductor channels
as weak links, the energy scale associated with the Josephson tunneling can be
changed with respect to the charging energy of the island, tuning the extent of
its charge fluctuations. Here, we directly demonstrate this control by mapping
the energy level structure of a CPT made of an indium arsenide nanowire (NW)
with a superconducting aluminum shell. We extract the device parameters based
on the exhaustive modeling of the quantum dynamics of the phase-biased nanowire
CPT and directly measure the even-odd parity occupation ratio as a function of
the device temperature, relevant for superconducting and prospective
topological qubits.Comment: Published version. Supplementary Information is available as
ancillary file, raw data and calculations can be downloaded from
http://doi.org/10.4121/uuid:5d54f11b-6774-4ae4-96cf-25e6a91927e
Observation of the 4-periodic Josephson effect in indium arsenide nanowires
Quantum computation by non-Abelian Majorana zero modes (MZMs) offers an
approach to achieve fault tolerance by encoding quantum information in the
non-local charge parity states of semiconductor nanowire networks in the
topological superconductor regime. Thus far, experimental studies of MZMs
chiefly relied on single electron tunneling measurements which leads to
decoherence of the quantum information stored in the MZM. As a next step
towards topological quantum computation, charge parity conserving experiments
based on the Josephson effect are required, which can also help exclude
suggested non-topological origins of the zero bias conductance anomaly. Here we
report the direct measurement of the Josephson radiation frequency in InAs
nanowires with epitaxial aluminium shells. For the first time, we observe the
-periodic Josephson effect above a magnetic field of mT,
consistent with the estimated and measured topological phase transition of
similar devices.Comment: Published version. Supplementary Information is available as
ancillary file, raw data and calculations can be downloaded from
http://dx.doi.org/10.4121/uuid:1f936840-5bc2-40ca-8c32-1797c12cacb
Observation of 2e-periodic Supercurrents in Nanowire Single-Cooper-Pair Transistors
Parity control of superconducting islands hosting Majorana zero modes (MZMs)
is required to operate topological qubits made from proximitized semiconductor
nanowires. We, therefore, study parity effects in hybrid InAs-Al
single-Cooper-pair transistors (SCPTs) as a first step. In particular, we
investigate the gate-charge supercurrent modulation and observe a consistent
2-periodic pattern indicating a general lack of low-energy subgap states in
these nanowires at zero magnetic field. In a parallel magnetic field, an
even-odd pattern develops with a gate-charge spacing that oscillates as a
function of field demonstrating that the modulation pattern is sensitive to the
presence of a single subgap state. In addition, we find that the parity
lifetime of the SCPT decreases exponentially with magnetic field as the subgap
state approaches zero energy. Our work highlights the important role that
intentional quasiparticle traps and superconducting gap engineering would play
in topological qubits that require quenching of the island charge dispersion.Comment: 8 pages, 4 figures, supplemental material included as ancillary fil
Josephson radiation and shot noise of a semiconductor nanowire junction
\u3cp\u3eWe measured the Josephson radiation emitted by an InSb semiconductor nanowire junction utilizing photon-assisted quasiparticle tunneling in an ac-coupled superconducting tunnel junction. We quantify the action of the local microwave environment by evaluating the frequency dependence of the inelastic Cooper-pair tunneling of the nanowire junction and find the zero-frequency impedance Z(0)=492Ω with a cutoff frequency of f0=33.1GHz. We extract a circuit coupling efficiency of η≈0.1 and a detector quantum efficiency approaching unity in the high-frequency limit. In addition to the Josephson radiation, we identify a shot noise contribution with a Fano factor F≈1, consistently with the presence of single electron states in the nanowire channel.\u3c/p\u3
Data underlying the paper: Broadband microwave spectroscopy of semiconductor nanowire-based Cooper-pair transistors
Raw data and scripts that belong to the paper "Broadband microwave spectroscopy of semiconductor nanowire-based
Cooper-pair transistors". For usage instructions, see readme.txt
Josephson radiation and shot noise of a semiconductor nanowire junction [version 1]
Raw data and code that belong to the paper "Josephson radiation and shot noise of a semiconductor nanowire junction". For usage instructions, see README.txt
Observation of the 4Ï€-periodic Josephson effect in InAs nanowires
Raw data and code that belong to the paper "Observation of the 4Ï€-periodic Josephson effect in InAs nanowires". For usage instructions, see readme.txt in the experiment and theory folder, respectively