Temperature-dependent electron mobility in InAs nanowires

The superconducting proximity effect is probed experimentally in Josephson junctions fabricated with InAs nanowires contacted by Nb leads. Contact transparencies [Formula: see text] are observed. The electronic phase coherence length at low temperatures exceeds the channel length. However, the elastic scattering length is a few times shorter than the channel length. Electrical measurements reveal two regimes of quantum transport: (i) the Josephson regime, characterised by a dissipationless current up to ∼100 nA, and (ii) the quantum dot (QD) regime, characterised by the formation of Andreev bound states (ABS) associated with spontaneous QDs inside the nanowire channel. In regime (i), the behaviour of the critical current I versus an axial magnetic field [Formula: see text] shows an unexpected modulation and persistence to fields [Formula: see text] T. In the QD regime, the ABS are modelled as the current-biased solutions of an Anderson-type model. The applicability of devices in both transport regimes to Majorana fermion experiments is discussed.

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“…Ar [26,27]. Devices d3 and d5 were on the same chip; otherwise each device is representative of a distinct fabrication run.…”

Section: Nanowirementioning

confidence: 99%

“…Table 1 reports the field effect mobilities µ obtained from transconductance measurements at T 50 K via the analysis given in Ref. [26]. The capacitance between the nanowire and the global backgate is estimated using a COMSOL model.…”

Section: Nanowirementioning

confidence: 99%

Nb/InAs nanowire proximity junctions from Josephson to quantum dot regimes

et al. 2017

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“…[19][20][21][22][23][24] To date, charge carrier transport properties of semiconductor nanowires are commonly studied through nanowire field-effect transistors. 7,8,20,[24][25][26][27][28][29][30] Alternatively, they can be obtained by nanoprobing an individual nanowire in a scanning electron microscope (SEM) environment. 19,[21][22][23] This nanoprobing technique provides the distinct advantage that the surface and interface properties of nanowires are not perturbed by any chemical treatment or photolithography process.…”

mentioning

confidence: 99%

Probing the electrical transport properties of intrinsic InN nanowires

Zhao

Salehzadeh

Alagha

et al. 2013

Applied Physics Letters

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We have studied the electrical transport properties of intrinsic InN nanowires using an electrical nanoprobing technique in a scanning electron microscope environment. It is found that such intrinsic InN nanowires exhibit an ohmic conduction at low bias and a space charge limited conduction at high bias. It is further derived that such InN nanowires can exhibit a free carrier concentration as low as ∼1013 cm−3 and possess a very large electron mobility in the range of 8000–12 000 cm2/V s, approaching the theoretically predicted maximum electron mobility at room temperature. In addition, charge traps are found to distribute exponentially just below the conduction band edge, with a characteristic energy ∼65 meV.

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“…Crystal structure is another main concern in III-V NWs, since structure polytypism [17][18][19] and planar defects (such as stacking defaults (SFs) and twins) have been popularly observed, which are unwanted for related device applications [20]. However, the well-controlled synthesis of III-V NWs with a pure wurtzite (WZ) or zinc blende (ZB) phase can also bring about new application possibilities, since different crystal structures can lead to different band gaps [21][22][23] and, in turn, different electronic and optical properties.…”

Section: Introductionmentioning

confidence: 99%

Evolution of morphology and microstructure of GaAs/GaSb nanowire heterostructures

Shi¹,

Zhang²,

Lu³

et al. 2016

Nano Online

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In this paper, we successfully grow GaAs/GaSb core-shell heterostructure nanowires (NWs) by molecular beam epitaxy (MBE). The as-grown GaSb shell layer forms a wurtzite structure instead of the zinc blende structure that has been commonly reported. Meanwhile, a bulgy GaSb nanoplate also appears on top of GaAs/GaSb core-shell NWs and possesses a pure zinc blende phase. The growth mode for core-shell morphology and underlying mechanism for crystal phase selection of GaAs/GaSb nanowire heterostructures are discussed in detail.

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Temperature-dependent electron mobility in InAs nanowires

Cited by 36 publications

References 51 publications

Nb/InAs nanowire proximity junctions from Josephson to quantum dot regimes

Nb/InAs nanowire proximity junctions from Josephson to quantum dot regimes

Probing the electrical transport properties of intrinsic InN nanowires

Evolution of morphology and microstructure of GaAs/GaSb nanowire heterostructures

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