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Keywords = Majorana fermions

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15 pages, 289 KB  
Article
Geometric Structures and Gauge Symmetries for Various Fermionic Fields from a Faddeev–Jackiw–Dirac Argument
by Eugen-Mihaita Cioroianu and Stefan Sabin Manolescu
Symmetry 2025, 17(11), 1953; https://doi.org/10.3390/sym17111953 - 13 Nov 2025
Viewed by 492
Abstract
This paper focuses on the identification of presymplectic/symplectic structures, as well as gauge symmetries, for various fermionic fields in four spacetime dimensions, using a combined Faddeev–Jackiw–Dirac approach. The intrinsic first-order dynamics of fermionic fields allow a straightforward Faddeev–Jackiw analysis, which avoids unnecessary primary [...] Read more.
This paper focuses on the identification of presymplectic/symplectic structures, as well as gauge symmetries, for various fermionic fields in four spacetime dimensions, using a combined Faddeev–Jackiw–Dirac approach. The intrinsic first-order dynamics of fermionic fields allow a straightforward Faddeev–Jackiw analysis, which avoids unnecessary primary second-class constraints, introduces no artificial hierarchies, and, in general, constitutes a foolproof strategy when combined with the Dirac method. The Majorana spinors and Majorana spinor-vectors, with dynamics of various orders, as fundamental constituents of all SUSY and SUGRA paradigms, are here taken into consideration. Their Faddeev–Jackiw–Dirac analysis exhibits several symplectic/presymplectic structures, which represent the main novelty, together with the reconfirmation of their gauge symmetries. Full article
21 pages, 419 KB  
Article
The Impact of Electric Currents on Majorana Dark Matter at Freeze Out
by Lukas Karoly and David C. Latimer
Universe 2025, 11(2), 66; https://doi.org/10.3390/universe11020066 - 14 Feb 2025
Viewed by 1265
Abstract
Thermal relics with masses in the GeV to TeV range remain possible candidates for the Universe’s dark matter (DM). These neutral particles are often assumed to have vanishing electric and magnetic dipole moments so that they do not interact with single real photons, [...] Read more.
Thermal relics with masses in the GeV to TeV range remain possible candidates for the Universe’s dark matter (DM). These neutral particles are often assumed to have vanishing electric and magnetic dipole moments so that they do not interact with single real photons, but the anapole moment, a static electromagnetic property whose features are akin to that of a classical toroidal solenoid, can still be non-zero, permitting interactions with single virtual photons. In some models, DM predominantly annihilates into charged standard model particles through a p-wave process mediated by the anapole moment. The anapole moment is also responsible for another interaction of interest. If a DM medium were subjected to an electric current, a DM particle whose anapole moment was aligned with the current would have lower energy than the state with an antialigned anapole moment. Given these interactions, if a collection of initially unpolarized DM particles were subjected to an electric current, then the DM medium would become partially polarized, according to the Boltzmann distribution. In such a polarized medium, DM annihilation into photons, a subdominant s-wave process realizable through higher order interactions, would be somewhat suppressed. If the local electric current existed during a time in which the DM begins to drop out of thermal equilibrium with the rest of the Universe, the suppressed annihilation could lead to a small local excess in the relic DM density relative to a current-free region. This mechanism by which the local DM density can be perturbed is novel. Using effective interactions to model a DM particle’s anapole moment and polarizabilities (responsible for s-wave annihilation into two photons), we compute the changes in the DM density produced by long- and short-lived currents around freeze out. If we employ the most stringent constraints on DM annihilation into two photons, we find that long-lived currents can result in a fractional change in the DM density on the order of 1017 for DM masses around 100 GeV; for short-lived currents, this fractional change in local DM density is on the order of 1023 for the same DM mass. Full article
(This article belongs to the Section High Energy Nuclear and Particle Physics)
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10 pages, 2123 KB  
Article
Topological Phase Diagram of an Interacting Kitaev Chain: Mean Field versus DMRG Study
by Giovanni Nunziante, Alfonso Maiellaro, Claudio Guarcello and Roberta Citro
Condens. Matter 2024, 9(1), 20; https://doi.org/10.3390/condmat9010020 - 20 Mar 2024
Viewed by 5180
Abstract
In this work, we study the topological phase transitions of a Kitaev chain generalized by the addition of nearest-neighbor Coulomb interaction. We show the presence of a robust topological phase as a function of the interaction strength and of the on-site energy with [...] Read more.
In this work, we study the topological phase transitions of a Kitaev chain generalized by the addition of nearest-neighbor Coulomb interaction. We show the presence of a robust topological phase as a function of the interaction strength and of the on-site energy with associated non-zero energy Majorana states localized at the chain edges. We provide an effective mean-field model that allows for the self-consistent computation of the mean value of the local particle number operator, and we also perform Density Matrix Renormalization Group numerical simulations based on a tensor network approach. We find that the two methods show a good agreement in reporting the phase transition between trivial and topological superconductivity. Temperature robustness within a physically relevant threshold has also been demonstrated. These findings shed light on an entire class of topological interacting one-dimensional systems in which the effects of residual Coulomb interactions play a relevant role. Full article
(This article belongs to the Special Issue Multicomponent Superconductivity and Superfluidity)
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13 pages, 490 KB  
Article
Thermophase Seebeck Coefficient in Hybridized Superconductor-Quantum-Dot-Superconductor Josephson Junction Side-Coupled to Majorana Nanowire
by Yumei Gao, Xiaoyan Zhang, Zichuan Yi, Liming Liu and Feng Chi
Nanomaterials 2023, 13(17), 2489; https://doi.org/10.3390/nano13172489 - 4 Sep 2023
Cited by 3 | Viewed by 2154
Abstract
The dc Josephson current is generated from phase difference between two superconductors separated by a mesoscopic thin film (Josephson junction) without external bias voltage. In the presence of a temperature gradient across the superconductors, a thermal phase is induced under the condition of [...] Read more.
The dc Josephson current is generated from phase difference between two superconductors separated by a mesoscopic thin film (Josephson junction) without external bias voltage. In the presence of a temperature gradient across the superconductors, a thermal phase is induced under the condition of open circuit. This is very similar to the Seebeck effect in the usual thermoelectric effect, and the thermal phase is thus named as thermophase Seebeck coefficient (TPSC). Here we find obvious enhancement and sign change of the TPSC unique to the Josephson junction composing of two superconductors connected to a semiconductor quantum dot (QD), which is additionally side-coupled to a nanowire hosting Majorana bound states (MBSs), the system denoted by S-MQD-S. These result arise from the newly developed states near the Fermi level of the superconductors due to the QD-MBS hybridization when the dot level is within the superconducting gap. The sign change of the TPSC provides a strong evidence of the existence of MBSs, and is absent if the QD is coupled to regular fermion, such as another QD (system denoted by S-DQD-S). We show that the magnitude and sign of the TPSC are sensitive to the physical quantities including interaction strength between the QD and MBSs, direct overlap between the MBSs, system equilibrium temperature, as well as hopping amplitude between the QD and the superconductors. The obtained results are explained with the help of the current-carrying density of the states (CCDOS), and may be useful in interdisciplinary research areas of Josephson and Majorana physics. Full article
(This article belongs to the Special Issue 2D and Carbon Nanomaterials for Energy Conversion and Storage)
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17 pages, 804 KB  
Article
Majorana Excitons in a Kitaev Chain of Semiconductor Quantum Dots in a Nanowire
by Mahan Mohseni, Hassan Allami, Daniel Miravet, David J. Gayowsky, Marek Korkusinski and Pawel Hawrylak
Nanomaterials 2023, 13(16), 2293; https://doi.org/10.3390/nano13162293 - 9 Aug 2023
Cited by 7 | Viewed by 2776
Abstract
We present here a theory of Majorana excitons, photo-excited conduction electron-valence band hole pairs, interacting with Majorana Fermions in a Kitaev chain of semiconductor quantum dots embedded in a nanowire. Using analytical tools and exact diagonalization methods, we identify the presence of Majorana [...] Read more.
We present here a theory of Majorana excitons, photo-excited conduction electron-valence band hole pairs, interacting with Majorana Fermions in a Kitaev chain of semiconductor quantum dots embedded in a nanowire. Using analytical tools and exact diagonalization methods, we identify the presence of Majorana zero modes in the nanowire absorption spectra. Full article
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28 pages, 3347 KB  
Review
Interacting with Futuristic Topological Quantum Materials: A Potential Candidate for Spintronics Devices
by Prashant Kumar, Ravi Kumar, Sanjeev Kumar, Manoj Kumar Khanna, Ravinder Kumar, Vinod Kumar and Akanksha Gupta
Magnetochemistry 2023, 9(3), 73; https://doi.org/10.3390/magnetochemistry9030073 - 2 Mar 2023
Cited by 7 | Viewed by 6254
Abstract
Spintronics, also known as magneto-electronics or spin transport electronics, uses the magnetic moment of the electron due to intrinsic spin along with its electric charge. In the present review, the topological insulators (2D, 3D, and hydride) were discussed including the conducting edge of [...] Read more.
Spintronics, also known as magneto-electronics or spin transport electronics, uses the magnetic moment of the electron due to intrinsic spin along with its electric charge. In the present review, the topological insulators (2D, 3D, and hydride) were discussed including the conducting edge of 2D topological insulators (TIs). Preparation methods of TIs along with fundamental properties, such as low power dissipation and spin polarized electrons, have been explored. Magnetic TIs have been extensively discussed and explained. Weyl phases, topological superconductors, and TIs are covered in this review. We have focused on creating novel spintronic gadgets based on TIs which have metallic topological exterior facades that are topologically defended and have an insulating bulk. In this review, topological phases are discussed as a potential candidate for novel quantum phenomena and new technological advances for fault-tolerant quantum computation in spintronics, low-power electronics, and as a host for Majorana fermions are elucidated. Room temperature stable magnetic skyrmions and anti-skyrmions in spintronics for next-generation memory/storage devices have been reported. Full article
(This article belongs to the Special Issue Spin and Charge Transport in Novel Quantum and Topological Materials)
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6 pages, 288 KB  
Proceeding Paper
Dark Matter Investigation Using Double Beta Decay Experiments
by Francesco Nozzoli and Cinzia Cernetti
Phys. Sci. Forum 2023, 7(1), 29; https://doi.org/10.3390/ECU2023-14056 - 17 Feb 2023
Viewed by 1724
Abstract
Nuclei that are unstable with respect to double beta decay are potentially interesting for a novel Dark Matter (DM) direct detection approach. In particular, a Majorana DM fermion inelastically scattering on a double beta unstable nucleus could stimulate its decay. Thanks to the [...] Read more.
Nuclei that are unstable with respect to double beta decay are potentially interesting for a novel Dark Matter (DM) direct detection approach. In particular, a Majorana DM fermion inelastically scattering on a double beta unstable nucleus could stimulate its decay. Thanks to the exothermic nature of the stimulated double beta decay, this detection approach would allow for also investigating light DM fermions, a class of DM candidates that evade the detection capability of the traditional elastic scattering experiments. The upper limits on the nucleus scattering cross sections and the expected signal distribution for different DM masses are shown and compared with the existing data for the case of the 76Ge nucleus. Full article
(This article belongs to the Proceedings of The 2nd Electronic Conference on Universe)
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9 pages, 2542 KB  
Communication
Observations of Nematicity, Dopants, and Zero-Bias Conductance Peaks for the Ca0.9La0.1FeAs2 Superconductor
by Jae-Joon Kim, Min Seok Park, Kyoung Seok Lee, Sang Hyun Joo, Jung Hoon Yoo, Dilip Bhoi, Byeong Hun Min, Kee Hoon Kim and Jinho Lee
Nanomaterials 2023, 13(4), 622; https://doi.org/10.3390/nano13040622 - 4 Feb 2023
Cited by 2 | Viewed by 2473
Abstract
Ca1−xLaxFeAs2 (CLFA112) belongs to a new family of Fe-based superconductors (FeSCs) and has a unique crystal structure featuring an arsenic zigzag chain layer, which has been proposed to be a possible two-dimensional topological insulator. This suggests that CLFA112 [...] Read more.
Ca1−xLaxFeAs2 (CLFA112) belongs to a new family of Fe-based superconductors (FeSCs) and has a unique crystal structure featuring an arsenic zigzag chain layer, which has been proposed to be a possible two-dimensional topological insulator. This suggests that CLFA112 is a potential topological superconductor—a platform to realize Majorana fermions. Up to now, even a clear superconducting (SC) gap in CLFA112 has never been observed, and the SC properties of CLFA112 remain largely elusive. In this letter, we report the results of an atomic-scale investigation of the electronic structure of CLFA112 crystals using low-temperature scanning tunneling microscopy (STM). We revealed four different types of surfaces exhibiting distinct electronic properties, with all surfaces displaying dominating 2 × 1 surface reconstructions. On a Ca/La layer on top of an FeAs layer, a clear SC gap of ~12 mV was observed only at the crevices (vacancies) where the FeAs layer can be directly accessed. Remarkably, the FeAs termination layer displayed a dispersing nematic modulation both in real and q space. We also present peculiar zero-bias conductance peaks for the very As chain layer that is believed to exhibit a topological edge state as well as the influence of La dopants on the As chain layer. Full article
(This article belongs to the Special Issue Super-resolution Microscopy and Nanoscience)
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29 pages, 493 KB  
Article
Beyond the Standard Model with Six-Dimensional Spinors
by David Chester, Alessio Marrani and Michael Rios
Particles 2023, 6(1), 144-172; https://doi.org/10.3390/particles6010008 - 28 Jan 2023
Cited by 24 | Viewed by 6156
Abstract
Six-dimensional spinors with Spin(3,3) symmetry are utilized to efficiently encode three generations of matter. E8(24) is shown to contain physically relevant subgroups with representations for GUT groups, spacetime symmetries, three [...] Read more.
Six-dimensional spinors with Spin(3,3) symmetry are utilized to efficiently encode three generations of matter. E8(24) is shown to contain physically relevant subgroups with representations for GUT groups, spacetime symmetries, three generations of the standard model fermions, and Higgs bosons. Pati–Salam, SU(5), and Spin(10) grand unified theories are found when a single generation is isolated. For spacetime symmetries, Spin(4,2) may be used for conformal symmetry, AdS5dS4, or simply broken to Spin(3,1) of a Minkowski space. Another class of representations finds Spin(2,2) and can give AdS3 with various GUTs. An action for three generations of fermions in the Majorana–Weyl spinor 128 of Spin(4,12) is found with Spin(3) flavor symmetry inside E8(24). The 128 of Spin(12,4) can be regarded as the tangent space to a particular pseudo-Riemannian form of the octo-octonionic Rosenfeld projective plane E8(24)/Spin(12,4)=(OsxO)P2. Full article
(This article belongs to the Special Issue Particles: Feature Papers)
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27 pages, 5685 KB  
Article
Topological Defects Created by Gamma Rays in a Carbon Nanotube Bilayer
by Halina Grushevskaya, Andrey Timoshchenko and Ihor Lipnevich
Nanomaterials 2023, 13(3), 410; https://doi.org/10.3390/nano13030410 - 19 Jan 2023
Cited by 11 | Viewed by 3395
Abstract
Graphene sheets are a highly radiation-resistant material for prospective nuclear applications and nanoscale defect engineering. However, the precise mechanism of graphene radiation hardness has remained elusive. In this paper, we study the origin and nature of defects induced by gamma radiation in a [...] Read more.
Graphene sheets are a highly radiation-resistant material for prospective nuclear applications and nanoscale defect engineering. However, the precise mechanism of graphene radiation hardness has remained elusive. In this paper, we study the origin and nature of defects induced by gamma radiation in a graphene rolled-up plane. In order to reduce the environmental influence on graphene and reveal the small effects of gamma rays, we have synthesized a novel graphene-based nanocomposite material containing a bilayer of highly aligned carbon nanotube assemblies that have been decorated by organometallic compounds and suspended on nanoporous Al2O3 membranes. The bilayer samples were irradiated by gamma rays from a 137Cs source with a fluence rate of the order of 105 m2s1. The interaction between the samples and gamma quanta results in the appearance of three characteristic photon escape peaks in the radiation spectra. We explain the mechanism of interaction between the graphene sheets and gamma radiation using a pseudo-Majorana fermion graphene model, which is a quasi-relativistic N=3-flavor graphene model with a Majorana-like mass term. This model admits the existence of giant charge carrier currents that are sufficient to neutralize the impact of ionizing radiation. Experimental evidence is provided for the prediction that the 661.7-keV gamma quanta transfer enough energy to the electron subsystem of graphene to bring about the deconfinement of the bound pseudo-Majorana modes and involve C atoms in a vortical motion of the electron density flows in the graphene plane. We explain the radiation hardness of graphene by the topological non-triviality of the pseudo-Majorana fermion configurations comprising the graphene charge carriers. Full article
(This article belongs to the Special Issue Nanomaterials for Advanced Optics and Photonics)
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22 pages, 594 KB  
Article
Relativistic Fermion and Boson Fields: Bose-Einstein Condensate as a Time Crystal
by Valeriy Sbitnev
Symmetry 2023, 15(2), 275; https://doi.org/10.3390/sym15020275 - 18 Jan 2023
Cited by 3 | Viewed by 4174
Abstract
In a basis of the space-time coordinate frame four quaternions discovered by Hamilton can be used. For subsequent reproduction of the coordinate frame these four quaternions are expanded to four 4 × 4 matrices with real-valued matrix coefficients −0 and 1. This group [...] Read more.
In a basis of the space-time coordinate frame four quaternions discovered by Hamilton can be used. For subsequent reproduction of the coordinate frame these four quaternions are expanded to four 4 × 4 matrices with real-valued matrix coefficients −0 and 1. This group set is isomorphic to the SU(2) group. Such a matrix basis introduces extra six degrees of freedom of matter motion in space-time. There are three rotations about three space axes and three boosts along these axes. Next one declares the differential generating operators acting on the energy-momentum density tensor written in the above quaternion basis. The subsequent actions of this operator together with its transposed one on the above tensor lead to the emergence of the gravitomagnetic equations that are like the Maxwell equations. Wave equations extracted from the gravitomagnetic ones describe the propagation of energy density waves and their vortices through space. The Dirac equations and their reduction to two equations with real-valued functions, the quantum Hamilton-Jacobi equations and the continuity equations, are considered. The Klein-Gordon equations arising on the mass shell hints to the alternation of the paired fermion fields and boson ones. As an example, a Feynman diagram of an electron–positron time crystal is illustrated. Full article
(This article belongs to the Special Issue Symmetry and Asymmetry in Quantum Mechanics)
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25 pages, 11076 KB  
Article
Generating Many Majorana Corner Modes and Multiple Phase Transitions in Floquet Second-Order Topological Superconductors
by Longwen Zhou
Symmetry 2022, 14(12), 2546; https://doi.org/10.3390/sym14122546 - 2 Dec 2022
Cited by 10 | Viewed by 3595
Abstract
A d-dimensional, nth-order topological insulator or superconductor has localized eigenmodes at its (dn)-dimensional boundaries (nd). In this work, we apply periodic driving fields to two-dimensional superconductors, and obtain a wide variety of [...] Read more.
A d-dimensional, nth-order topological insulator or superconductor has localized eigenmodes at its (dn)-dimensional boundaries (nd). In this work, we apply periodic driving fields to two-dimensional superconductors, and obtain a wide variety of Floquet second-order topological superconducting (SOTSC) phases with many Majorana corner modes at both zero and π quasienergies. Two distinct Floquet SOTSC phases are found to be separated by three possible kinds of transformations, i.e., a topological phase transition due to the closing/reopening of a bulk spectral gap, a topological phase transition due to the closing/reopening of an edge spectral gap, or an entirely different phase in which the bulk spectrum is gapless. Thanks to the strong interplay between driving and intrinsic energy scales of the system, all the found phases and transitions are highly controllable via tuning a single hopping parameter of the system. Our discovery not only enriches the possible forms of Floquet SOTSC phases, but also offers an efficient scheme to generate many coexisting Majorana zero and π corner modes, which may find applications in Floquet quantum computation. Full article
(This article belongs to the Special Issue Topological Phases and Symmetry: Latest Advances and Prospects)
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15 pages, 387 KB  
Review
Double Beta Decay: A Shell Model Approach
by Mihai Horoi
Physics 2022, 4(4), 1135-1149; https://doi.org/10.3390/physics4040074 - 26 Sep 2022
Cited by 6 | Viewed by 3893
Abstract
Studies of weak interaction in nuclei are important tools for testing different aspects of the fundamental symmetries of the Standard Model. Neutrinoless double beta decay offers an unique venue of investigating the possibility that neutrinos are Majorana fermions and that the lepton number [...] Read more.
Studies of weak interaction in nuclei are important tools for testing different aspects of the fundamental symmetries of the Standard Model. Neutrinoless double beta decay offers an unique venue of investigating the possibility that neutrinos are Majorana fermions and that the lepton number conservation law is violated. Here, I use a shell model approach to calculate the nuclear matrix elements needed to extract the lepton-number-violating parameters of a few nuclei of experimental interest from the latest experimental lower limits of neutrinoless double beta decay half-lives. The analysis presented here could reveal valuable information regarding the dominant neutrinoless double beta decay mechanism if experimental half-life data become available for different isotopes. A complementary shell model analysis of the two-neutrino double beta decay nuclear matrix elements and half-lives is also presented. Full article
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22 pages, 4921 KB  
Article
Majorana Anyon Composites in Magneto-Photoluminescence Spectra of Natural Quantum Hall Puddles
by Alexander M. Mintairov, Dmitrii V. Lebedev, Alexey S. Vlasov and Steven A. Blundell
Nanomaterials 2022, 12(6), 1016; https://doi.org/10.3390/nano12061016 - 20 Mar 2022
Cited by 4 | Viewed by 3703
Abstract
In magneto-photoluminescence (magneto-PL) spectra of quasi two-dimensional islands (quantum dots) having seven electrons and Wigner–Seitz radius rs~1.5, we revealed a suppression of magnetic field (B) dispersion, paramagnetic shifts, and jumps of the energy of the emission components for filling [...] Read more.
In magneto-photoluminescence (magneto-PL) spectra of quasi two-dimensional islands (quantum dots) having seven electrons and Wigner–Seitz radius rs~1.5, we revealed a suppression of magnetic field (B) dispersion, paramagnetic shifts, and jumps of the energy of the emission components for filling factors ν > 1 (B < 10 T). Additionally, we observed B-hysteresis of the jumps and a dependence of all these anomalous features on rs. Using a theoretical description of the magneto-PL spectra and an analysis of the electronic structure of these dots based on the single-particle Fock–Darwin spectrum and many-particle configuration-interaction calculations, we show that these observations can be described by the rs-dependent formation of the anyon (magneto-electron) composites (ACs) involving single-particle states having non-zero angular momentum and that the anyon states observed involve Majorana modes (MMs), including zero-B modes having an equal number of vortexes and anti-vortexes, which can be considered as Majorana anyons. We show that the paramagnetic shift corresponds to a destruction of the equilibrium self-formed ν~5/2 AC by the external magnetic field and that the jumps and their hysteresis can be described in terms of Majorana qubit states controlled by B and rs. Our results show a critical role of quantum confinement in the formation of magneto-electrons and implies the liquid-crystal nature of fractional quantum Hall effect states, the Majorana anyon origin of the states having even ν, i.e., composite fermions, which provide new opportunities for topological quantum computing. Full article
(This article belongs to the Special Issue Quantum Dots)
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13 pages, 9562 KB  
Article
Topological Phases of an Interacting Majorana Benalcazar–Bernevig–Hughes Model
by Alfonso Maiellaro, Fabrizio Illuminati and Roberta Citro
Condens. Matter 2022, 7(1), 26; https://doi.org/10.3390/condmat7010026 - 4 Mar 2022
Cited by 10 | Viewed by 4234
Abstract
We study the effects of Coulomb repulsive interactions on a Majorana Benalcazar–Bernevig–Huges (MBBH) model. The MBBH model belongs to the class of second-order topological superconductors (HOTSC2), featuring robust Majorana corner modes. We consider an interacting strip [...] Read more.
We study the effects of Coulomb repulsive interactions on a Majorana Benalcazar–Bernevig–Huges (MBBH) model. The MBBH model belongs to the class of second-order topological superconductors (HOTSC2), featuring robust Majorana corner modes. We consider an interacting strip of four chains of length L and perform a density matrix renormalization group (DMRG) numerical simulation based on a tensor-network approach. Study of the non-local fermionic correlations and the degenerate entanglement spectrum indicates that the topological phases are robust in the presence of interactions, even in the strongly interacting regime. Full article
(This article belongs to the Special Issue Computational Methods for Quantum Matter)
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