Your search keyword '"Governale, M."' showing total 153 results

1. Odd-frequency superfluidity from a particle-number-conserving perspective

Author

Thompson, K., Zülicke, U., Schmalian, J., Governale, M., and Brand, J.

Subjects

Condensed Matter - Superconductivity, Condensed Matter - Quantum Gases

Abstract

We investigate odd-in-time - or odd-frequency - pairing of fermions in equilibrium systems within the particle-number-conserving framework of Penrose, Onsager and Yang, where superfluid order is defined by macroscopic eigenvalues of reduced density matrices. We show that odd-frequency pair correlations are synonymous with even fermion-exchange symmetry in a time-dependent correlation function that generalises the two-body reduced density matrix. Macroscopic even-under-fermion-exchange pairing is found to emerge from conventional Penrose-Onsager-Yang condensation in two-body or higher-order reduced density matrices through the symmetry-mixing properties of the Hamiltonian. We identify and characterise a transformer matrix responsible for producing macroscopic even fermion-exchange correlations that coexist with a conventional Cooper-pair condensate, while a generator matrix is shown to be responsible for creating macroscopic even fermion-exchange correlations from hidden orders such as a multi-particle condensate. The transformer scenario is illustrated using the spin-balanced s-wave superfluid with Zeeman splitting as an example. The generator scenario is demonstrated by the composite-boson condensate arising for itinerant electrons coupled to magnetic excitations. Structural analysis of the transformer and generator matrices is shown to provide general conditions for odd-frequency pairing order to arise in a given system. Our formalism facilitates a fully general derivation of the Meissner effect for odd-frequency superconductors that holds also beyond the regime of validity for mean-field theory., Comment: 23 pages, 2 figures, RevTex4.2

Published

2024

2. Spherical topological-insulator nanoparticles: Quantum size effects and optical transitions

Author

Gioia, L., Christie, M. G., Zülicke, U., Governale, M., and Sneyd, A. J.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We have investigated the interplay between band inversion and size quantization in spherically shaped nanoparticles made from topological-insulator (TI) materials. A general theoretical framework is developed based on a versatile continuum-model description of the TI bulk band structure and the assumption of a hard-wall mass confinement. Analytical results are obtained for the wave functions of single-electron energy eigenstates and the matrix elements for optical transitions between them. As expected from spherical symmetry, quantized levels in TI nanoparticles can be labeled by quantum numbers $j$ and $m=-j, -j+1, \dots, j$ for total angular momentum and its projection on an arbitrary axis. The fact that TIs are narrow-gap materials, where the charge-carrier dynamics is described by a type of two-flavor Dirac model, requires $j$ to assume half-integer values and also causes a doubling of energy-level degeneracy where two different classes of states are distinguished by being parity eigenstates with eigenvalues $(-1)^{j\mp 1/2}$. The existence of energy eigenstates having the same $j$ but opposite parity enables optical transitions where $j$ is conserved, in addition to those adhering to the familiar selection rule where $j$ changes by $\pm 1$. All optical transitions satisfy the usual selection rule $\Delta m = 0, \pm 1$. We treat intra- and inter-band optical transitions on the same footing and establish ways for observing unusual quantum-size effects in TI nanoparticles, including oscillatory dependences of the band gap and of transition amplitudes on the nanoparticle radius. Our theory also provides a unified perspective on multi-band models for charge carriers in semiconductors and Dirac fermions from elementary-particle physics., Comment: 13 pages, 4 figures, RevTex4.2, v2: extended discussion of optical transitions, including new Figs. 3 & 4, to appear in PRB

Published

2019

3. Community structure in co-inventor networks affects time to first citation for patents

Author

Doonan, W., Higham, K. W., Governale, M., and Zülicke, U.

Subjects

Computer Science - Social and Information Networks, Physics - Physics and Society

Abstract

We have investigated community structure in the co-inventor network of a given cohort of patents and related this structure to the dynamics of how these patents acquire their first citation. A statistically significant difference in the time lag until first citation is linked to whether or not this citation comes from a patent whose listed inventors share membership in the same communities as the inventors of the cited patent. Although the inventor-community structures identified by different community-detection algorithms differ in several aspects, including the community-size distribution, the magnitude of the difference in time to first citation is robustly exhibited. Our work is able to quantify the expected acceleration of knowledge flow within inventor communities and thereby further establishes the utility of network-analysis tools for studying innovation dynamics., Comment: 16 pages, 4 figures, BioMedCentral article style, to appear in Applied Network Science - special issue 'Community structure in networks'

Published

2019

4. Ex-ante measure of patent quality reveals intrinsic fitness for citation-network growth

Author

Higham, K. W., Governale, M., Jaffe, A. B., and Zülicke, U.

Subjects

Physics - Physics and Society, Computer Science - Digital Libraries

Abstract

We have constructed a fitness parameter, characterizing the intrinsic attractiveness for patents to be cited, from attributes of the associated inventions known at the time a patent is granted. This exogenously obtained fitness is shown to determine the temporal growth of the citation network in conjunction with mechanisms of preferential attachment and obsolescence-induced ageing that operate without reference to characteristics of individual patents. Our study opens a window on understanding quantitatively the interplay of the rich-gets-richer and fit-gets-richer paradigms that have been suggested to govern the growth dynamics of real-world complex networks., Comment: 6 pages, 3 figures, RevTex4.1, v2: minor changes, version to appear as a Rapid Communication in Phys. Rev. E

Published

2019

5. Dirac electrons in quantum rings

Author

Gioia, L., Zülicke, U., Governale, M., and Winkler, R.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We consider quantum rings realized in materials where the dynamics of charge carriers mimics that of two-dimensional (2D) Dirac electrons. A general theoretical description of the ring-subband structure is developed that applies to a range of currently available 2D systems, including graphene, transition-metal dichalcogenides, and narrow-gap semiconductor quantum wells. We employ the scattering-matrix approach to calculate the electronic two-terminal conductance through the ring and investigate how it is affected by Dirac-electron interference. The interplay of pseudo-spin chirality and hard-wall confinement is found to distinctly affect the geometric phase that is experimentally accessible in mesoscopic-conductance measurements. We derive an effective Hamiltonian for the azimuthal motion of charge carriers in the ring that yields deeper insight into the physical origin of the observed transport effects, including the unique behavior exhibited by the lowest ring subband in the normal and topological (i.e., band-inverted) regimes. Our work provides a unified approach to characterizing confined Dirac electrons, which can be used to explore the design of valley- and spintronic devices based on quantum interference and the confinement-tunable geometric phase., Comment: 17 pages, 10 figures, RevTex4.1, v2: version to appear in PRB, v3: final published version

Published

2018

6. Unraveling the dynamics of growth, aging and inflation for citations to scientific articles from specific research fields

Author

Higham, K. W., Governale, M., Jaffe, A. B., and Zülicke, U.

Subjects

Computer Science - Digital Libraries, Computer Science - Social and Information Networks, Physics - Physics and Society

Abstract

We analyze the time evolution of citations acquired by articles from journals of the American Physical Society (PRA, PRB, PRC, PRD, PRE and PRL). The observed change over time in the number of papers published in each journal is considered an exogenously caused variation in citability that is accounted for by a normalization. The appropriately inflation-adjusted citation rates are found to be separable into a preferential-attachment-type growth kernel and a purely obsolescence-related (i.e., monotonously decreasing as a function of time since publication) aging function. Variations in the empirically extracted parameters of the growth kernels and aging functions associated with different journals point to research-field-specific characteristics of citation intensity and knowledge flow. Comparison with analogous results for the citation dynamics of technology-disaggregated cohorts of patents provides deeper insight into the basic principles of information propagation as indicated by citing behavior., Comment: 13 pages, 6 figures, Elsevier style, v2: revised version to appear in J. Informetrics

Published

2017

7. Fame and Obsolescence: Disentangling growth and ageing dynamics of patent citations

Author

Higham, K. W., Governale, M., Jaffe, A. B., and Zülicke, U.

Subjects

Physics - Physics and Society, Computer Science - Digital Libraries

Abstract

We present an analysis of citations accrued over time by patents granted by the United States Patent and Trademark Office in 1998. In contrast to previous studies, a disaggregation by technology category is performed, and exogenously caused citation-number growth is controlled for. Our approach reveals an intrinsic citation rate that clearly separates into an -- in the long run, exponentially time-dependent -- ageing function and a completely time-independent preferential-attachment-type growth kernel. For the general case of such a separable citation rate, we obtain the time-dependent citation distribution analytically in a form that is valid for any functional form of its ageing and growth parts. Good agreement between theory and long-time characteristics of patent-citation data establishes our work as a useful framework for addressing still open questions about knowledge-propagation dynamics, such as the observed excess of citations at short times., Comment: 8 pages, 5 Figures, RevTex4.1, to appear in Phys. Rev. E. v2: additional results and more detailed discussion

Published

2016

8. Unconventional superconductivity from magnetism in transition metal dichalcogenide

Author

Rahimi, M. A., Moghaddam, A. G., Dykstra, C., Governale, M., and Zülicke, U.

Subjects

Condensed Matter - Superconductivity, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We investigate proximity-induced superconductivity in monolayers of transition metal dichalcogenides (TMDs) in the presence of an externally generated exchange field. A variety of superconducting order parameters is found to emerge from the interplay of magnetism and superconductivity, covering the entire spectrum of possibilities to be symmetric or antisymmetric with respect to the valley and spin degrees of freedom, as well as even or odd in frequency. More specifically, when a conventional \emph{s}-wave superconductor with singlet Copper pairs is tunnel-coupled to the TMD layer, both spin-singlet and triplet pairings between electrons from the same and opposite valleys arise due to the combined effects of intrinsic spin-orbit coupling and a magnetic-substrate-induced exchange field. As a key finding, we reveal the existence of an exotic even-frequency triplet pairing between equal-spin electrons from different valleys, which arises whenever the spin orientations in the two valleys are noncollinear. All types of superconducting order turn out to be highly tunable via straightforward manipulation of the external exchange field., Comment: 8 pages, 4 figures

Published

2016

9. Quantum capacitance of an HgTe quantum well as an indicator of the topological phase

Author

Kernreiter, T., Governale, M., and Zülicke, U.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Varying the quantum-well width in an HgTe/CdTe heterostructure allows to realize normal and inverted semiconducting band structures, making it a prototypical system to study two-dimensional (2D) topological-insulator behavior. We have calculated the zero-temperature thermodynamic density of states $D_\mathrm{T}$ for the electron-doped situation in both regimes, treating interactions within the Hartree-Fock approximation. A distinctively different behavior for the density dependence of $D_\mathrm{T}$ is revealed in the inverted and normal cases, making it possible to detect the system's topological order through measurement of macroscopic observables such as the quantum capacitance or electronic compressibility. Our results establish the 2D electron system in HgTe quantum wells as unique in terms of its collective electronic properties., Comment: 6 pages, 7 figures, v2: minor changes, version to appear as Rapid Communication in Phys. Rev. B

Published

2016

10. Anomalous Spin Response and Virtual-Carrier-Mediated Magnetism in a Topological Insulator

Author

Kernreiter, T., Governale, M., Zülicke, U., and Hankiewicz, E. M.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science

Abstract

We present a comprehensive theoretical study of the static spin response in HgTe quantum wells, revealing distinctive behavior for the topologically nontrivial inverted structure. Most strikingly, the q=0 (long-wave-length) spin susceptibility of the undoped topological-insulator system is constant and equal to the value found for the gapless Dirac-like structure, whereas the same quantity shows the typical decrease with increasing band gap in the normal-insulator regime. We discuss ramifications for the ordering of localized magnetic moments present in the quantum well, both in the insulating and electron-doped situations. The spin response of edge states is also considered, and we extract effective Lande g-factors for the bulk and edge electrons. The variety of counter-intuitive spin-response properties revealed in our study arises from the system's versatility in accessing situations where the charge-carrier dynamics can be governed by ordinary Schrodinger-type physics, mimics the behavior of chiral Dirac fermions, or reflects the material's symmetry-protected topological order., Comment: 15 pages, 8 figures, RevTex4.1; v2: extended and expanded results and presentation

Published

2015

11. Superconductivity in the ferromagnetic semiconductor SmN

Author

Anton, E. -M., Granville, S., Engel, A., Chong, S. V., Governale, M., Zülicke, U., Moghaddam, A. G., Trodahl, H. J., Natali, F., Vézian, S., and Ruck, B. J.

Subjects

Condensed Matter - Superconductivity

Abstract

The discovery of materials that simultaneously host different phases of matter has often initially confounded, but ultimately enhanced, our basic understanding of the coexisting types of order. The associated intellectual challenges, together with the promise of greater versatility for potential applications, have made such systems a focus of modern materials science. In particular, great efforts have recently been devoted to making semiconductors ferromagnetic and metallic ferromagnets superconducting. Here we report the unprecedented observation of a heavily donor-doped ferromagnetic semiconductor, SmN, becoming superconducting with ferromagnetism remaining intact. The extremely large exchange splitting of the conduction and valence bands in this material necessitates that the superconducting order hosted by SmN is of an unconventional triplet type, most likely exhibiting p-wave symmetry. Short range spin fluctuations, which are thought to be the cause of pairing interactions in currently known triplet superconductors, are quenched in SmN, suggesting its superconductivity to be the result of phonon- or Coulomb-mediated pairing mechanisms. This scenario is further supported by the inferred heavy mass of superconducting charge carriers. The unique near-zero magnetisation associated with the ferromagnetic state in SmN further aids its coexistence with superconductivity. Presenting this novel material system where semiconducting, ferromagnetic and superconducting properties are combined provides a versatile new laboratory for studying quantum phases of matter. Moreover it is a major step towards identifying materials that merge superconductivity and spintronics, urgently needed to enable the design of electronic devices with superior functionality., Comment: 8 pages, 5 figures, main text plus supplemental material

Published

2015

12. Coulomb-exchange effects in nanowires with spin splitting due to a radial electric field

Author

Gray, F. S., Kernreiter, T., Governale, M., and Zuelicke, U.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We present a theoretical study of Coulomb exchange interaction for electrons confined in a cylindrical quantum wire and subject to a Rashba-type spin-orbit coupling with radial electric field. The effect of spin splitting on the single-particle band dispersions, the quasiparticle effective mass, and the system's total exchange energy per particle are discussed. Exchange interaction generally suppresses the quasiparticle effective mass in the lowest nanowire subband, and a finite spin splitting is found to significantly increase the magnitude of the quasiparticle-mass suppression (by upto 15\% in the experimentally relevant parameter regime). In contrast, spin-orbit coupling causes a modest (1\%-level) reduction of the magnitude of the exchange energy per particle. Our results shed new light on the interplay of spin-orbit coupling and Coulomb interaction in quantum-confined systems, including those that are expected to host exotic quasiparticle excitations., Comment: 9 pages, 8 figures; v2 includes new results for the quasiparticle effective mass (to appear in Phys. Rev. B)

Published

2015

13. Exporting superconductivity across the gap: Proximity effect for semiconductor valence-band states due to contact with a simple-metal superconductor

Author

Moghaddam, A. G., Kernreiter, T., Governale, M., and Zuelicke, U.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The proximity effect refers to the phenomenon whereby superconducting properties are induced in a normal conductor that is in contact with an intrinsically superconducting material. In particular, the combination of nano-structured semiconductors with bulk superconductors is of interest because these systems can host unconventional electronic excitations such as Majorana fermions when the semiconductor's charge carriers are subject to a large spin-orbit coupling. The latter requirement generally favors the use of hole-doped semiconductors. On the other hand, basic symmetry considerations imply that states from typical simple-metal superconductors will predominantly couple to a semiconductor's conduction-band states and, therefore, in the first instance generate a proximity effect for band electrons rather than holes. In this article, we show how the superconducting correlations in the conduction band are transferred also to hole states in the valence band by virtue of inter-band coupling. A general theory of the superconducting proximity effect for bulk and low-dimensional hole systems is presented. The interplay of inter-band coupling and quantum confinement is found to result in unusual wave-vector dependencies of the induced superconducting gap parameters. One particularly appealing consequence is the density tunability of the proximity effect in hole quantum wells and nanowires, which creates new possibilities for manipulating the transition to nontrivial topological phases in these systems., Comment: 10 pages, 3 figures, RevTex 4.1, v2: now showing nanowire results for InAs (instead of GaAs in v1), to appear in Phys. Rev. B

Published

2014

14. Suppression of Coulomb exchange energy in quasi-two-dimensional hole systems

Author

Kernreiter, T., Governale, M., Winkler, R., and Zuelicke, U.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science

Abstract

We have calculated the exchange-energy contribution to the total energy of quasi-two-dimensional hole systems realized by a hard-wall quantum-well confinement of valence-band states in typical semiconductors. The magnitude of the exchange energy turns out to be suppressed from the value expected for analogous conduction-band systems whenever the mixing between heavy-hole and light-hole components is strong. Our results are obtained using a very general formalism for calculating the exchange energy of many-particle systems where single-particle states are spinors. We have applied this formalism to obtain analytical results for spin-3/2 hole systems in limiting cases., Comment: 9 pages, 3 figures, RevTex 4.1, v2: minor changes

Published

2013

15. Carrier-density-controlled anisotropic spin susceptibility of two-dimensional hole systems

Author

Kernreiter, T., Governale, M., and Zuelicke, U.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We have studied quantum-well-confined holes based on the Luttinger-model description for the valence band of typical semiconductor materials. Even when only the lowest quasi-two-dimensional (quasi-2D) subband is populated, the static spin susceptibility turns out to be very different from the universal isotropic Lindhard-function lineshape obtained for 2D conduction-electron systems. The strongly anisotropic and peculiarly density-dependent spin-related response of 2D holes at long wavelengths should make it possible to switch between easy-axis and easy-plane magnetization in dilute magnetic quantum wells. An effective g factor for 2D hole systems is proposed., Comment: 5+1 pages, 4+1 figures, RevTex 4.1, article + suppl. material to appear in Phys. Rev. Letters

Published

2012

16. Charge transport by modulating spin-orbit gauge fields for quasi-onedimensional holes

Author

Kernreiter, T., Governale, M., Hamilton, A. R., and Zuelicke, U.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We present a theoretical study of ac charge transport arising from adiabatic temporal variation of zero-field spin splitting in a quasi-onedimensional hole system (realized, e.g., in a quantum wire or point contact). As in conduction-electron systems, part of the current results from spin-dependent electromotive forces. We find that the magnitude of this current contribution is two orders of magnitude larger for holes and exhibits parametric dependences that make it more easily accessible experimentally. Our results suggest hole structures to be good candidates for realizing devices where spin currents are pumped by time-varying electric fields., Comment: 4 pages, 3 figures, RevTex4.1

Published

2011

17. A Josephson Quantum Electron Pump

Author

Giazotto, F., Spathis, P., Roddaro, S., Biswas, S., Taddei, F., Governale, M., and Sorba, L.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Superconductivity

Abstract

A macroscopic fluid pump works according to the law of Newtonian mechanics and transfers a large number of molecules per cycle (of the order of 10^23). By contrast, a nano-scale charge pump can be thought as the ultimate miniaturization of a pump, with its operation being subject to quantum mechanics and with only few electrons or even fractions of electrons transfered per cycle. It generates a direct current in the absence of an applied voltage exploiting the time-dependence of some properties of a nano-scale conductor. The idea of pumping in nanostructures was discussed theoretically a few decades ago [1-4]. So far, nano-scale pumps have been realised only in system exhibiting strong Coulombic effects [5-12], whereas evidence for pumping in the absence of Coulomb-blockade has been elusive. A pioneering experiment by Switkes et al. [13] evidenced the difficulty of modulating in time the properties of an open mesoscopic conductor at cryogenic temperatures without generating undesired bias voltages due to stray capacitances [14,15]. One possible solution to this problem is to use the ac Josephson effect to induce periodically time-dependent Andreev-reflection amplitudes in a hybrid normal-superconducting system [16]. Here we report the experimental detection of charge flow in an unbiased InAs nanowire (NW) embedded in a superconducting quantum interference device (SQUID). In this system, pumping may occur via the cyclic modulation of the phase of the order parameter of different superconducting electrodes. The symmetry of the current with respect to the enclosed magnetic flux [17,18] and bias SQUID current is a discriminating signature of pumping. Currents exceeding 20 pA are measured at 250 mK, and exhibit symmetries compatible with a pumping mechanism in this setup which realizes a Josephson quantum electron pump (JQEP)., Comment: 7+ pages, 6 color figures

Published

2011

18. Static polarizability of two-dimensional hole gases

Author

Kernreiter, T., Governale, M, and Zuelicke, U.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We have calculated the density-density (Lindhard) response function of a homogeneous two-dimensional (2D) hole gas in the static (omega=0) limit. The bulk valence-band structure comprising heavy-hole (HH) and light-hole (LH) states is modeled using Luttinger's kdotp approach within the axial approximation. We elucidate how, in contrast to the case of conduction electrons, the Lindhard function of 2D holes exhibits unique features associated with (i) the confinement-induced HH-LH energy splitting and (ii) the HH-LH mixing arising from the charge carriers' in-plane motion. Implications for the dielectric response and related physical observables are discussed., Comment: 11 pages, 3 figures, IOP latex style, v2: minor changes, to appear in NJP

Published

2010

19. Landau Cooling in Metal-Semiconductor Nanostructures

Author

Giazotto, F., Taddei, F., Governale, M., Fazio, R., and Beltram, F.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

An electron-cooling principle based on Landau quantization is proposed for nanoscale conductor systems. Operation relies on energy-selective electron tunneling into a two-dimensional electron gas in quantizing magnetic fields. This quantum refrigerator provides significant cooling power (~1 nW at a few K for realistic parameters) and offers a unique flexibility thanks to its tunability via the magnetic-field intensity. The available performance is only marginally affected by nonidealities such as disorder or imperfections in the semiconductor. Methods for the implementation of this system and its characterization are discussed., Comment: 4 pages, 4 color figures

Published

2007

20. Cooling electrons by magnetic-field tuning of Andreev reflection

Author

Giazotto, F., Taddei, F., Governale, M., Castellana, C., Fazio, R., and Beltram, F.

Subjects

Condensed Matter - Superconductivity, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

A solid-state cooling principle based on magnetic-field-driven tunable suppression of Andreev reflection in superconductor/two-dimensional electron gas nanostructures is proposed. This cooling mechanism can lead to very large heat fluxes per channel up to 10^4 times greater than currently achieved with superconducting tunnel junctions. This efficacy and its availability in a two-dimensional electron system make this method of particular relevance for the implementation of quantum nanostructures operating at cryogenic temperatures., Comment: 4 pages, 4 figures, published version

Published

2006

21. Superconductor-semiconductor magnetic microswitch

Author

Castellana, C., Giazotto, F., Governale, M., Taddei, F., and Beltram, F.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Superconductivity

Abstract

A hybrid superconductor--two-dimensional electron gas microdevice is presented. Its working principle is based on the suppression of Andreev reflection at the superconductor-semiconductor interface caused by a magnetic barrier generated by a ferromagnetic strip placed on top of the structure. Device switching is predicted with fields up to some mT and working frequencies of several GHz, making it promising for applications ranging from microswitches and storage cells to magnetic field discriminators., Comment: 4 pages, 3 figures, minor changes to text

Published

2005

22. Adiabatic pumping in a Superconductor-Normal-Superconductor weak link

Author

Governale, M., Taddei, F., Hekking, F. W. J., and Fazio, Rosario

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Superconductivity

Abstract

We present a formalism to study adiabatic pumping through a superconductor - normal - superconductor weak link. At zero temperature, the pumped charge is related to the Berry phase accumulated, in a pumping cycle, by the Andreev bound states. We analyze in detail the case when the normal region is short compared to the superconducting coherence length. The pumped charge turns out to be an even function of the superconducting phase difference. Hence, it can be distinguished from the charge transferred due to the standard Josephson effect., Comment: 4 pages, 2 figures; Fig. 2 replaced, minor changes in the text

Published

2005

23. Andreev reflection and cyclotron motion at superconductor -- normal-metal interfaces

Author

Giazotto, F., Governale, M., Zuelicke, U., and Beltram, F.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Superconductivity

Abstract

We investigate Andreev reflection at the interface between a superconductor and a two--dimensional electron system (2DES) in an external magnetic field such that cyclotron motion is important in the latter. A finite Zeeman splitting in the 2DES and the presence of diamagnetic screening currents in the superconductor are incorporated into a microscopic theory of Andreev edge states, which is based on the Bogoliubov--de Gennes formalism. The Andreev--reflection contribution to the interface conductance is calculated. The effect of Zeeman splitting is most visible as a double--step feature in the conductance through clean interfaces. Due to a screening current, conductance steps are shifted to larger filling factors and the formation of Andreev edge states is suppressed below a critical filling factor., Comment: 8 pages, 6 figures

Published

2005

24. Anti-crossings of spin-split Landau levels in an InAs two-dimensional electron gas with spin-orbit coupling

Author

Desrat, W., Giazotto, F., Pellegrini, V., Governale, M., Beltram, F., Capotondi, F., Biasiol, G., and Sorba, L.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We report tilted-field transport measurements in the quantum-Hall regime in an InAs/In_0.75Ga_0.25As/In_0.75Al_0.25As quantum well. We observe anti-crossings of spin-split Landau levels, which suggest a mixing of spin states at Landau level coincidence. We propose that the level repulsion is due to the presence of spin-orbit and of band-non-parabolicity terms which are relevant in narrow-gap systems. Furthermore, electron-electron interaction is significant in our structure, as demonstrated by the large values of the interaction-induced enhancement of the electronic g-factor., Comment: 4 pages, 3 figures

Published

2005

25. Rashba spin splitting in quantum wires

Author

Governale, M. and Zuelicke, U.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

This article presents an overview of results pertaining to electronic structure, transport properties, and interaction effects in ballistic quantum wires with Rashba spin splitting. Limits of weak and strong spin--orbit coupling are distinguished, and spin properties of the electronic states elucidated. The case of strong Rashba spin splitting where the spin--precession length is comparable to the wire width turns out to be particularly interesting. Hybridization of spin--split quantum--wire subbands leads to an unusual spin structure where the direction of motion for electrons can fix their spin state. This peculiar property has important ramifications for linear transport in the quantum wire, giving rise to spin accumulation without magnetic fields or ferromagnetic contacts. A description for interacting Rashba--split quantum wires is developed, which is based on a generalization of the Tomonaga--Luttinger model., Comment: 16 pages, 7 figures, to appear in Solid State Communications

Published

2004

26. Pumping spin with electrical fields

Author

Governale, M., Taddei, F., and Fazio, Rosario

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Spin currents can be obtained through adiabatic pumping by means of electrical gating only. This is possible by making use of the tunability of the Rashba spin-orbit coupling in semiconductor heterostructures. We demonstrate the principles of this effect by considering a single-channel wire with a constriction. We also consider realistic structures, consisting of several open channels where subband spin-mixing and disorder are present, and we confirm our predictions. Two different ways to detect the spin-pumping effect, either using ferromagnetic leads or applying a magnetic field, are discussed., Comment: 5 pages, 2 figures; minor changes, typos corrected

Published

2002

27. Magnetic Field Effects on the Transport Properties of One-sided Rough Wires

Author

García-Martín, A., Governale, M., and Wölfle, P.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We present a detailed numerical analysis of the effect of a magnetic field on the transport properties of a `small-$N$' one-sided surface disordered wire. When time reversal symmetry is broken due to a magnetic field $B$, we find a strong increase with $B$ not only of the localization length $\xi$ but also of the mean free path $\ell$ caused by boundary states. Despite this, the universal relationship between $\ell$ and $\xi$ does hold. We also analyze the conductance distribution at the metal-insulator crossover, finding a very good agreement with Random Matrix Theory with two fluctuating channels within the Circular Orthogonal(Unitary) Ensemble in absence(presence) of $B$, Comment: 5 pages, 4 figures, to appear in Phys. Rev. B

Published

2002

28. Quantum dots with Rashba spin-orbit coupling

Author

Governale, M.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We present results on the effects of spin-orbit coupling on the electronic structure of few-electron interacting quantum dots. The ground-state properties as a function of the number of electrons in the dot $N$ are calculated by means of spin density functional theory. We find a suppression of Hund's rule due to the competition of the Rashba effect and exchange interaction. Introducing an in-plane Zeeman field leads to a paramagnetic behavior of the dot in a closed shell configuration, and to spin texture in space., Comment: 5 pages, 3 figures, revised version, to appear in Phys. Rev. Lett

Published

2002

29. Momentum-Resolved Tunneling into Fractional Quantum Hall Edges

Author

Zuelicke, U., Shimshoni, E., and Governale, M.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Tunneling from a two-dimensional contact into quantum-Hall edges is considered theoretically for a case where the barrier is extended, uniform, and parallel to the edge. In contrast to previously realized tunneling geometries, details of the microscopic edge structure are exhibited directly in the voltage and magnetic-field dependence of the differential tunneling conductance. In particular, it is possible to measure the dispersion of the edge-magnetoplasmon mode, and the existence of additional, sometimes counterpropagating, edge-excitation branches could be detected., Comment: 4 pages, 3 figures, RevTex4

Published

2002

30. Spin Accumulation in Quantum Wires with Strong Rashba Spin-Orbit Coupling

Author

Governale, M. and Zuelicke, U.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Strongly Correlated Electrons

Abstract

We present analytical and numerical results for the effect of Rashba spin-orbit coupling on band structure, transport, and interaction effects in quantum wires when the spin precession length is comparable to the wire width. In contrast to the weak-coupling case, no common spin-quantization axis can be defined for eigenstates within a single-electron band. The situation with only the lowest spin-split subbands occupied is particularly interesting because electrons close to Fermi points of the same chirality can have approximately parallel spins. We discuss consequences for spin-dependent transport and effective Tomonaga-Luttinger descriptions of interactions in the quantum wire., Comment: 4 pages, 4 figures, expanded discussion of spin accumulation

Published

2002

31. Filtering spin with tunnel-coupled electron wave guides

Author

Governale, M., Boese, D., Zuelicke, U., and Schroll, C.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We show how momentum-resolved tunneling between parallel electron wave guides can be used to observe and exploit lifting of spin degeneracy due to Rashba spin-orbit coupling. A device is proposed that achieves spin filtering without using ferromagnets or the Zeeman effect., Comment: 4 pages, 4 figures, RevTex4

Published

2001

32. Probing Spin-Charge Separation in Tunnel-Coupled Parallel Quantum Wires

Author

Zuelicke, U. and Governale, M.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Interactions in one-dimensional (1D) electron systems are expected to cause a dynamical separation of electronic spin and charge degrees of freedom. A promising system for experimental observation of this non-Fermi-liquid effect consists of two quantum wires coupled via tunneling through an extended uniform barrier. Here we consider the minimal model of an interacting 1D electron system exhibiting spin-charge separation and calculate the differential tunneling conductance as well as the density-density response function. Both quantities exhibit distinct strong features arising from spin-charge separation. Our analysis of these features within the minimal model neglects interactions between electrons of opposite chirality and applies therefore directly to chiral 1D electron systems realized, e.g., at the edge of integer quantum-Hall systems. Physical insight gained from our results is useful for interpreting current experiment in quantum wires as our main conclusions still apply with nonchiral interactions present. In particular, we discuss the effect of charging due to applied voltages, and the possibility to observe spin-charge separation in a time-resolved experiment., Comment: 9 pages, 3 figures, expanded version with many details

Published

2001

33. Operation of Quantum Cellular Automaton cells with more than two electrons

Author

Girlanda, M., Governale, M., Macucci, M., and Iannaccone, G.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Strongly Correlated Electrons

Abstract

We present evidence that operation of QCA (Quantum Cellular Automaton) cells with four dots is possible with an occupancy of 4N+2 electrons per cell (N being an integer). We show that interaction between cells can be described in terms of a revised formula for cell polarization, which is based only on the difference between diagonal occupancies. We validate our conjectures with full quantum simulations of QCA cells for a number of electrons varying from 2 to 6, using the Configuration-Interaction method., Comment: 4 pages, 4 figures included, submitted to APL

Published

1999

34. Simulation of a non-invasive charge detector for quantum cellular automata

Author

Iannaccone, G., Ungarelli, C., Macucci, M., Amirante, E., and Governale, M.

Subjects

Condensed Matter

Abstract

Information in a Quantum Cellular Automata architecture is encoded in the polarizazion state of a cell, i.e., in the occupation numbers of the quantum dots of which the cell is made up. Non-invasive charge detectors of single electrons in a quantum dot are therefore needed, and recent experiments have shown that a quantum constriction electrostatically coupled to the quantum dot may be a viable solution. We have performed a numerical simulation of a system made of a quantum dot and a nearby quantum point contact defined, by means of depleting metal gates, in a two-dimensional electron gas at a GaAs/AlGaAs heterointerface. We have computed the occupancy of each dot and the resistance of the quantum wire as a function of the voltage applied to the plunger gate, and have derived design criteria for achieving optimal sensitivity., Comment: 8 pages, RevTeX, epsf, 5 figures

Published

1998

35. Modeling and manufacturability assessment of bistable quantum-dot cells

Author

Governale, M., Macucci, M., Iannaccone, G., Ungarelli, C., and Martorell, J.

Subjects

Condensed Matter

Abstract

We have investigated the behavior of bistable cells made up of four quantum dots and occupied by two electrons, in the presence of realistic confinement potentials produced by depletion gates on top of a GaAs/AlGaAs heterostructure. Such a cell represents the basic building block for logic architectures based on the concept of Quantum Cellular Automata (QCA) and of ground state computation, which have been proposed as an alternative to traditional transistor-based logic circuits. We have focused on the robustness of the operation of such cells with respect to asymmetries deriving from fabrication tolerances. We have developed a 2-D model for the calculation of the electron density in a driven cell in response to the polarization state of a driver cell. Our method is based on the one-shot Configuration-Interaction technique, adapted from molecular chemistry. From the results of our simulations, we conclude that an implementation of QCA logic based on simple ``hole-arrays'' is not feasible, because of the extreme sensitivity to fabrication tolerances. As an alternative, we propose cells defined by multiple gates, where geometrical asymmetries can be compensated for by adjusting the bias voltages. Even though not immediately applicable to the implementation of logic gates and not suitable for large scale integration, the proposed cell layout should allow an experimental demonstration of a chain of QCA cells., Comment: 26 pages, Revtex, 13 figures, title and some figures changed and minor revisions

Published

1998

36. Gauge invariant grid discretization of Schr\'odinger equation

Author

Governale, M. and Ungarelli, C.

Subjects

Condensed Matter, High Energy Physics - Lattice

Abstract

Using the Wilson formulation of lattice gauge theories, a gauge invariant grid discretization of a one-particle Hamiltonian in the presence of an external electromagnetic field is proposed. This Hamiltonian is compared both with that obtained by a straightforward discretization of the continuous Hamiltonian by means of balanced difference methods, and with a tight-binding Hamiltonian. The proposed Hamiltonian and the balanced difference one are used to compute the energy spectrum of a charged particle in a two-dimensional parabolic potential in the presence of a perpendicular, constant magnetic field. With this example we point out how a "naive" discretization gives rise to an explicit breaking of the gauge invariance and to large errors in the computed eigenvalues and corresponding probability densities; in particular, the error on the eigenfunctions may lead to very poor estimates of the mean values of some relevant physical quantities on the corresponding states. On the contrary, the proposed discretized Hamiltonian allows a reliable computation of both the energy spectrum and the probability densities., Comment: 7 pages, 4 figures, discussion about tight-binding Hamiltonians added

Published

1998

37. Momentum-resolved tunneling: Spectroscopic tool and basis for device applications

Author

Governale, M., Zülicke, U., Fazio, R., editor, Gantmakher, V. F., editor, and Imry, Y., editor

Published

2003

38. Problems and Perspectives in Quantum-Dot Based Computation

Author

Macucci, M., Iannaccone, G., Francaviglia, S., Governale, M., Girlanda, M., Ungarelli, C., Pavesi, Lorenzo, editor, and Buzaneva, Eugenia, editor

Published

2000

39. Filtering Spin with Tunnel-Coupled Hole Quantum Wires

Author

Governale, M. and Zülicke, U.

Published

2003

40. Spherical topological insulator nanoparticles: Quantum size effects and optical transitions

Author

Gioia, L., primary, Christie, M. G., additional, Zülicke, U., additional, Governale, M., additional, and Sneyd, A. J., additional

Published

2019

41. Ex-ante measure of patent quality reveals intrinsic fitness for citation-network growth

Author

Higham, K. W., primary, Governale, M., additional, Jaffe, A. B., additional, and Zülicke, U., additional

Published

2019

42. Magnetotunneling between parallel quantum wires: from coherent oscillations to spin–charge separation

Author

Boese, D., Governale, M., Rosch, A., and Zülicke, U.

Published

2002

43. Entanglement-symmetry control in a quantum-dot Cooper-pair splitter

Author

Hussein R., Braggio A., and Governale M.

Subjects

Coulomb blockade, superconductor, Cooper-pair splitter, quantum dots, Quantum Physics, spin-orbit interaction, proximity effects, Condensed Matter::Mesoscopic Systems and Quantum Hall Effect, entanglement

Abstract

The control of nonlocal entanglement in solid state systems is a crucial ingredient of quantum technologies. We investigate a Cooper-pair splitter based on a double quantum dot realized in a semiconducting nanowire. In the presence of interdot tunneling the system provides a simple mechanism to develop spatial entanglement even in absence of nonlocal coupling with the superconducting lead. We discuss the possibility to control the symmetry (singlet or triplet) of spatially separated, entangled electron pairs taking advantage of the spin-orbit coupling of the nanowire. We also demonstrate that the spin-orbit coupling does not impact over the entanglement purity of the nonlocal state generated in the double quantum dot system. Cooper-pair splitter realized in a nanowire acting as double quantum dot which is coupled to one superconductor (S) and two normal leads (N). Electron singlets in the superconductor are split nonlocally into the different dots as schematically shown in the figure. The entangled electrons in the two quantum dots are then transferred by tunneling, with rate math formula, to the normal leads.

Published

2017

44. Dirac electrons in quantum rings

Author

Gioia, L., primary, Zülicke, U., additional, Governale, M., additional, and Winkler, R., additional

Published

2018

45. Unraveling the dynamics of growth, aging and inflation for citations to scientific articles from specific research fields

Author

Higham, K.W., primary, Governale, M., additional, Jaffe, A.B., additional, and Zülicke, U., additional

Published

2017

46. Fame and obsolescence: Disentangling growth and aging dynamics of patent citations

Author

Higham, K. W., primary, Governale, M., additional, Jaffe, A. B., additional, and Zülicke, U., additional

Published

2017

47. Unconventional superconductivity from magnetism in transition-metal dichalcogenides

Author

Rahimi, M. A., primary, Moghaddam, A. G., additional, Dykstra, C., additional, Governale, M., additional, and Zülicke, U., additional

Published

2017

48. Modeling and manufacturability assessment of bistable quantum-dot cells.

Author

Governale, M. and Macucci, M.

Subjects

*QUANTUM dots, *GALLIUM arsenide, *HETEROSTRUCTURES

Abstract

Presents information on a study which investigated the behavior of bistable quantum dot cells in the presence of realistic confinement potentials produced by depletion gates on top of a gallium arsenide/aluminum gallium arsenide heterostructure. Statement of the problem and cell model; Configuration-interaction method; Results and discussion; Conclusions.

Published

1999

49. Superconductivity in the ferromagnetic semiconductor samarium nitride

Author

Anton, E.-M., primary, Granville, S., additional, Engel, A., additional, Chong, S. V., additional, Governale, M., additional, Zülicke, U., additional, Moghaddam, A. G., additional, Trodahl, H. J., additional, Natali, F., additional, Vézian, S., additional, and Ruck, B. J., additional

Published

2016

50. Quantum capacitance of an HgTe quantum well as an indicator of the topological phase

Author

Kernreiter, T., primary, Governale, M., additional, and Zülicke, U., additional

Published

2016