Majorana fermions in semiconductor nanowires: fundamentals, modeling, and experiment

Abstract We use the SYK family of models with N Majorana fermions to study the complexity of time evolution, formulated as the shortest geodesic length on the unitary group manifold between the identity and the time evolution operator, in free, integrable, and chaotic systems. Initially, the shortest geodesic follows the time evolution trajectory, and hence complexity grows linearly in time. We study how this linear growth is eventually truncated by the appearance and accumulation of conjugate points, which signal the presence of shorter geodesics intersecting the time evolution trajectory. By explicitly locating such “shortcuts” through analytical and numerical methods, we demonstrate that: (a) in the free theory, time evolution encounters conjugate points at a polynomial time; consequently complexity growth truncates at O($$ \sqrt{N} $$ N ), and we find an explicit operator which “fast-forwards” the free N-fermion time evolution with this complexity, (b) in a class of interacting integrable theories, the complexity is upper bounded by O(poly(N)), and (c) in chaotic theories, we argue that conjugate points do not occur until exponential times O(eN), after which it becomes possible to find infinitesimally nearby geodesics which approximate the time evolution operator. Finally, we explore the notion of eigenstate complexity in free, integrable, and chaotic models.

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Electromagnetic field emitted by core–shell semiconductor nanowires driven by an alternating current

Journal of Applied Physics ◽

10.1063/5.0055260 ◽

2021 ◽

Vol 130 (3) ◽

pp. 034301

Author(s):

Miguel Urbaneja Torres ◽

Kristjan Ottar Klausen ◽

Anna Sitek ◽

Sigurdur I. Erlingsson ◽

Vidar Gudmundsson ◽

...

Keyword(s):

Electromagnetic Field ◽

Alternating Current ◽

Semiconductor Nanowires ◽

Core Shell

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Chaos on the hypercube

Journal of High Energy Physics ◽

10.1007/jhep11(2020)154 ◽

2020 ◽

Vol 2020 (11) ◽

Author(s):

Yiyang Jia ◽

Jacobus J. M. Verbaarschot

Keyword(s):

Magnetic Flux ◽

Spectral Density ◽

Hermite Polynomials ◽

Weighted Sums ◽

Majorana Fermions ◽

Chord Diagrams ◽

Magnetic Inversion ◽

Constant Magnitude ◽

Kitaev Model ◽

Spectral Statistics

Abstract We analyze the spectral properties of a d-dimensional HyperCubic (HC) lattice model originally introduced by Parisi. The U(1) gauge links of this model give rise to a magnetic flux of constant magnitude ϕ but random orientation through the faces of the hypercube. The HC model, which also can be written as a model of 2d interacting Majorana fermions, has a spectral flow that is reminiscent of Maldacena-Qi (MQ) model, and its spectrum at ϕ = 0, actually coincides with the coupling term of the MQ model. As was already shown by Parisi, at leading order in 1/d, the spectral density of this model is given by the density function of the Q-Hermite polynomials, which is also the spectral density of the double-scaled Sachdev-Ye-Kitaev model. Parisi demonstrated this by mapping the moments of the HC model to Q-weighted sums on chord diagrams. We point out that the subleading moments of the HC model can also be mapped to weighted sums on chord diagrams, in a manner that descends from the leading moments. The HC model has a magnetic inversion symmetry that depends on both the magnitude and the orientation of the magnetic flux through the faces of the hypercube. The spectrum for fixed quantum number of this symmetry exhibits a transition from regular spectra at ϕ = 0 to chaotic spectra with spectral statistics given by the Gaussian Unitary Ensembles (GUE) for larger values of ϕ. For small magnetic flux, the ground state is gapped and is close to a Thermofield Double (TFD) state.

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