15 results on '"Principi, Alessandro"'
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2. Topological engineering of terahertz light using electrically tunable exceptional point singularities
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Ergoktas, M. Said, Soleymani, Sina, Kakenov, Nurbek, Wang, Kaiyuan, Smith, Thomas B., Bakan, Gokhan, Balci, Sinan, Principi, Alessandro, Novoselov, Kostya S., Ozdemir, Sahin K., Kocabas, Coskun, and Kakenov, Nurbek
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Multidisciplinary ,Article - Abstract
The topological structure associated with the branch point singularity around an exceptional point (EP) can provide tools for controlling the propagation of light. Through use of graphene-based devices, we demonstrate the emergence of EPs in an electrically controlled interaction between light and a collection of organic molecules in the terahertz regime at room temperature. We show that the intensity and phase of terahertz pulses can be controlled by a gate voltage, which drives the device across the EP. Our electrically tunable system allows reconstruction of the Riemann surface associated with the complex energy landscape and provides topological control of light by tuning the loss imbalance and frequency detuning of interacting modes. Our approach provides a platform for developing topological optoelectronics and studying the manifestations of EP physics in light–matter interactions.
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- 2022
3. Grassmann phase space dynamics of strongly-correlated fermion
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Al-Hamzawi, Hassan, Principi, Alessandro, and Villari, Leone Di Mauro
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Quantum Gases (cond-mat.quant-gas) ,FOS: Physical sciences ,Condensed Matter - Quantum Gases - Abstract
We discuss the numerical implementation of two related representations of fermionic density matrices which have been introduced in Annals of Physics 370, 12 (2016). In both of them, the density matrix is expanded in a basis of Bargmann coherent states with weights given by the two phase space distributions. We derive the equations of motion for the distributions when imaginary time evolution is generated by the Hubbard Hamiltonian. One of them is a Grassmann Fokker-Planck equation that can be re-cast into a remarkably simple It\^{o} form involving solely complex variables. In spite of this simple form, we demonstrate that complications arise in numerically computing the expectation value of any observable. These are due to exponential growth in the matrix elements of the stochastic propagator, delicate numerical sensitivity in performing primitive linear algebra operations, and the re-appearance of a sign problem.
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- 2023
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4. Vison manipulation with local magnetic fields
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Wang, Haoran and Principi, Alessandro
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Condensed Matter - Strongly Correlated Electrons ,Condensed Matter - Mesoscale and Nanoscale Physics ,Strongly Correlated Electrons (cond-mat.str-el) ,Mesoscale and Nanoscale Physics (cond-mat.mes-hall) ,FOS: Physical sciences - Abstract
Quantum spin liquids hosting non-abelian anyons have recently experienced renewed interest following the discovery of a variety of materials proximate to these quantum phases. Their anyonic excitations have potential for application to topological quantum computation, but designing logical operations with reduced poisoning requires developing protocols to faithfully create, move and read-out such quasiparticles. In this paper, we present one such protocol for manipulating $Z_2$ fluxes (``visons'') of ferromagnetic and antiferromagnetic Kitaev models perturbed by a small uniform magnetic field. Our design employs a local driving magnetic field and can achieve high probabilities of generating and displacing flux pairs of both the $A_z$ and $B$ phases of the model.
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- 2023
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5. Rotating Majorana Zero Modes in a disk geometry
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Yang, Liu, Principi, Alessandro, and Walet, Niels R.
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Condensed Matter - Other Condensed Matter ,Quantum Physics ,FOS: Physical sciences ,Quantum Physics (quant-ph) ,Other Condensed Matter (cond-mat.other) - Abstract
We study the manipulation of Majorana zero modes in a thin disk made from a p-wave superconductor, in order to understand their use as a building block for topological quantum computers. We analyze the second-order topological corner modes that arise when an in-plane magnetic field is applied, and we calculate their dynamical evolution when rotating the magnetic field, with special emphasis on nonadiabatic effects. We characterize the phase transition between high-frequency and near-adiabatic evolution using Floquet analysis. We show that oscillations persist even in the adiabatic phase because of a frequency-independent coupling between zero modes and excited states, which we have quantified numerically and analytically. These results show that controlling the rotation frequency can be a simple method to avoid the nonadiabatic errors originated from this coupling and thus increase the robustness of topological quantum computation.
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- 2021
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6. Majorana corner states in square and Kagome quantum spin liquids
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Wang, Haoran and Principi, Alessandro
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Condensed Matter - Strongly Correlated Electrons ,Condensed Matter - Mesoscale and Nanoscale Physics ,Strongly Correlated Electrons (cond-mat.str-el) ,Mesoscale and Nanoscale Physics (cond-mat.mes-hall) ,FOS: Physical sciences ,Condensed Matter::Strongly Correlated Electrons - Abstract
Quantum spin liquids hosting Majorana excitations have recently experienced renewed interest for potential applications to topological quantum computation. Performing logical operations with reduced poisoning requires to localize such quasiparticles at specific point of the system, with energies that are well defined and inside the bulk energy gap. These are two defining features of second order topological insulators (SOTIs). Here, we show two spin models that support quantum spin liquid phases characterised by Majorana excitations and that behave as SOTIs, one of which is analytically solvable thanks to a theorem by Lieb. We show that, depending on the values of spin couplings, it is possible to localize either fermions or Majorana particles at their corners., Comment: 4+epsilon pages, 3 figures, 1 appendix (supplemental material - included in the main arXiv text)
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- 2021
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7. Hot carriers in graphene-fundamentals and applications
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Massicotte, Mathieu, Soavi, Giancarlo, Principi, Alessandro, Tielrooij, Klaas-Jan, Ministerio de Economía y Competitividad (España), National Research Council of Canada, Leverhulme Trust, and Daimler and Benz Foundation
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Hot charge carriers in graphene exhibit fascinating physical phenomena, whose understanding has improved greatly over the past decade. They have distinctly different physical properties compared to, for example, hot carriers in conventional metals. This is predominantly the result of graphene's linear energy-momentum dispersion, its phonon properties, its all-interface character, and the tunability of its carrier density down to very small values, and from electron- to hole-doping. Since a few years, we have witnessed an increasing interest in technological applications enabled by hot carriers in graphene. Of particular interest are optical and optoelectronic applications, where hot carriers are used to detect (photodetection), convert (nonlinear photonics), or emit (luminescence) light. Graphene-enabled systems in these application areas could find widespread use and have a disruptive impact, for example in the field of data communication, high-frequency electronics, and industrial quality control. The aim of this review is to provide an overview of the most relevant physics and working principles that are relevant for applications exploiting hot carriers in graphene. ICN2 was supported by the Severo Ochoa program from Spanish MINECO (grant no. SEV-2017-0706). K. J. T. acknowledges funding from the European Union's Horizon 2020 research and innovation program under grant agreement no. 804349 (ERC StG CUHL), RyC fellowship no. RYC-2017-22330, IAE project PID2019-111673GB-I00, and financial support through the MAINZ Visiting Professorship. G. S. acknowledges funding from the European Union's Horizon 2020 research and innovation program under grant agreement GrapheneCore3 881603, the German Research Foundation DFG (CRC 1375 NOA, project B5) and the Daimler und Benz foundation. M. M. acknowledges support from the Natural Sciences and Engineering Research Council of Canada (PDF-516936-2018) and from the Canada First Research Excellence Fund. A. P. is supported by the European Commission under the EU Horizon 2020 MSCA-RISE-2019 programme (project 873028 HYDROTRONICS). A. P. also acknowledges support of the Leverhulme Trust under the grant RPG-2019-363.
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- 2021
8. Thermal transport in compensated semimetals: a mystery explained
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Zarenia, Mohammad, Principi, Alessandro, and Vignale, Giovanni
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Condensed Matter - Mesoscale and Nanoscale Physics ,Mesoscale and Nanoscale Physics (cond-mat.mes-hall) ,FOS: Physical sciences - Abstract
It is well known that the electronic thermal conductivity of clean compensated semimetals can be greatly enhanced over the electric conductivity by the availability of an ambipolar mechanism of conduction, whereby electrons and holes flow in the same direction experiencing negligible Coulomb scattering as well as negligible impurity scattering. This enhancement -- resulting in a breakdown of the Wiedemann-Franz law with an anomalously large Lorenz ratio -- has been recently observed in two-dimensional monolayer and bilayer graphene near the charge neutrality point. In contrast to this, three-dimensional compensated semimetals such as WP$_2$ and Sb are typically found to show a reduced Lorenz ratio. This dramatic difference in behavior is generally attributed to different regimes of Fermi statistics in the two cases: degenerate electron-hole liquid in compensated semimetals versus non-degenerate electron-hole liquid in graphene. We show that this difference is not sufficient to explain the reduction of the Lorenz ratio in compensated semimetals. We argue that the solution of the puzzle lies in the ability of compensated semimetals to sustain sizeable regions of electron-hole accumulation near the contacts, which in turn is a consequence of the large separation of electron and hole pockets in momentum space. These accumulations suppress the ambipolar conduction mechanism and effectively split the system into two independent electron and hole conductors. We present a quantitative theory of the crossover from ambipolar to unipolar conduction as a function of the size of the electron-hole accumulation regions, and show that it naturally leads to a sample-size-dependent thermal conductivity., Comment: 9 pages, 5 figures
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- 2020
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9. Topological Surface-plasmon-polaritons on Corrugated Metal-dielectric Surfaces
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Smith, Thomas Benjamin, Kocabas, Coskun, and Principi, Alessandro
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Condensed Matter - Materials Science ,Condensed Matter - Mesoscale and Nanoscale Physics ,Mesoscale and Nanoscale Physics (cond-mat.mes-hall) ,Physics::Optics ,Materials Science (cond-mat.mtrl-sci) ,FOS: Physical sciences - Abstract
We study topological surface-plasmon-polaritons at optical frequencies in diffraction gratings formed by bipartite corrugated metal-dielectric gratings. To do so we implement the theory as developed in Della Valle and Longhi to describe the amplitude of the field by an emergent Schr\"odinger-like equation. The tri-harmonic grating generates a bipartite Kronig-Penney model. Topologically protected localised modes are then predicted to occur at the edges of the grating and at defects formed by the combination of two mirror antisymmetric corrugations, whose bulk invariant is a step-wise varying Zak phase in both cases., Comment: 6 pages of main, 9 pages of appendix, 5 figures
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- 2020
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10. Disorder-enabled hydrodynamics of charge and heat transport in monolayer graphene
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Zarenia, Mohammad, Principi, Alessandro, and Vignale, Giovanni
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Condensed Matter - Mesoscale and Nanoscale Physics ,Mesoscale and Nanoscale Physics (cond-mat.mes-hall) ,FOS: Physical sciences - Abstract
Hydrodynamic behavior in electronic systems is commonly accepted to be associated with extremely clean samples such that electron-electron collisions dominate and total momentum is conserved. Contrary to this, we show that in monolayer graphene the presence of disorder is essential to enable an unconventional hydrodynamic regime which exists near the charge neutrality point and is characterized by a large enhancement of the Wiedemann-Franz ratio. Although the enhancement becomes more pronounced with decreasing disorder, the very possibility of observing the effect depends crucially on the presence of disorder. We calculate the maximum extrinsic carrier density $n_c$ below which the effect becomes manifest, and show that $n_c$ vanishes in the limit of zero disorder. For $n>n_c$ we predict that the Wiedemann-Franz ratio actually decreases with decreasing disorder. We complete our analysis by presenting a transparent picture of the physical processes that are responsible for the crossover from conventional to disorder-enabled hydrodynamics. Recent experiments on monolayer graphene are discussed and shown to be consistent with this picture., 12 pages, 5 figures
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- 2018
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11. Negative electronic compressibility enables electrically-induced charge density waves in a two-dimensional electron liquid
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Hroblak, Erica E., Principi, Alessandro, Zhao, Hui, and Vignale, Giovanni
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Condensed Matter - Mesoscale and Nanoscale Physics ,Mesoscale and Nanoscale Physics (cond-mat.mes-hall) ,FOS: Physical sciences - Abstract
We show that the negative electronic compressibility of two-dimensional electronic systems at sufficiently low density enables the generation of charge density waves through the application of a uniform force field, provided no current is allowed to flow. The wavelength of the density oscillations is controlled by the magnitude of the (negative) screening length, and their amplitude is proportional to the applied force. Both are electrically tunable., Comment: 4 pages, 5 figures
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- 2017
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12. Edge pseudo-magnetoplasmons
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Principi, Alessandro, Katsnelson, Mikhail I., and Vignale, Giovanni
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Condensed Matter - Mesoscale and Nanoscale Physics ,Mesoscale and Nanoscale Physics (cond-mat.mes-hall) ,FOS: Physical sciences - Abstract
We study the properties of edge plasmons in two-component electron liquids in the presence of pseudomagnetic fields, which have opposite signs for the two different electronic populations and therefore preserve the time-reversal symmetry. The physical realizations of such systems are many. We discuss the cases of strained graphene and of electrons in proximity to a Skyrmion lattice, solving the problem with the Wiener-Hopf technique. We show (i) that two charged counter-propagating acoustic edge modes exist at the boundary and (ii) that, in the limit of large pseudomagnetic fields, each of them involves oscillations of only one of the two electronic components. We suggest that the edge pseudo-magnetoplasmons of graphene can be used to selectively address the electrons of one specific valley, a feature relevant for the emerging field of valleytronics. Conversely, the spin-polarized plasmons at the boundary of Skyrmion lattices can be exploited for spintronics applications. Our solution highlights new features missing in previous (similar) results obtained with uncontrolled approximations, namely a logarithmic divergence of the plasmon velocity, and the absence of gapped edge modes inside the bulk-plasmon gap., Comment: 4+6 pages, 2 figures
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- 2016
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13. Bulk and shear viscosities of the 2D electron liquid in a doped graphene sheet
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Principi, Alessandro, Vignale, Giovanni, Carrega, Matteo, and Polini, Marco
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Condensed Matter - Mesoscale and Nanoscale Physics ,Mesoscale and Nanoscale Physics (cond-mat.mes-hall) ,FOS: Physical sciences - Abstract
Hydrodynamic flow occurs in an electron liquid when the mean free path for electron-electron collisions is the shortest length scale in the problem. In this regime, transport is described by the Navier-Stokes equation, which contains two fundamental parameters, the bulk and shear viscosities. In this Article we present extensive results for these transport coefficients in the case of the two-dimensional massless Dirac fermion liquid in a doped graphene sheet. Our approach relies on microscopic calculations of the viscosities up to second order in the strength of electron-electron interactions and in the high-frequency limit, where perturbation theory is applicable. We then use simple interpolation formulae that allow to reach the low-frequency hydrodynamic regime where perturbation theory is no longer directly applicable. The key ingredient for the interpolation formulae is the "viscosity transport time" $\tau_{\rm v}$, which we calculate in this Article. The transverse nature of the excitations contributing to $\tau_{\rm v}$ leads to the suppression of scattering events with small momentum transfer, which are inherently longitudinal. Therefore, contrary to the quasiparticle lifetime, which goes as $-1/[T^2 \ln(T/T_{\rm F})]$, in the low temperature limit we find $\tau_{\rm v} \sim 1/T^2$., Comment: 27 pages, 6 figures, 5 appendices
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- 2015
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14. Accessing phonon polaritons in hyperbolic crystals by ARPES
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Tomadin, Andrea, Principi, Alessandro, Song, Justin C. W., Levitov, Leonid S., and Polini, Marco
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Condensed Matter - Mesoscale and Nanoscale Physics ,Mesoscale and Nanoscale Physics (cond-mat.mes-hall) ,Physics::Optics ,FOS: Physical sciences - Abstract
Recently studied hyperbolic materials host unique phonon-polariton (PP) modes. The ultra-short wavelengths of these modes, which can be much smaller than those of conventional exciton-polaritons, are of high interest for extreme sub-diffraction nanophotonics schemes. Polar hyperbolic materials such as hexagonal boron nitride can be used to realize strong long-range coupling between PP modes and extraneous charge degrees of freedom. The latter, in turn, can be used to control and probe PP modes. Of special interest is coupling between PP modes and plasmons in an adjacent graphene sheet, which opens the door to accessing PP modes by angle-resolved photoemission spectroscopy (ARPES). A rich structure in the graphene ARPES spectrum due to PP modes is predicted, providing a new probe of PP modes and their coupling to graphene plasmons.
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- 2015
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15. Out-of-plane heat transfer in van der Waals stacks through electron-hyperbolic phonon coupling
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Tielrooij, Klaas-Jan, Hesp, Niels CH, Principi, Alessandro, Lundeberg, Mark B, Pogna, Eva AA, Banszerus, Luca, Mics, Zoltán, Massicotte, Mathieu, Schmidt, Peter, Davydovskaya, Diana, Purdie, David G, Goykhman, Ilya, Soavi, Giancarlo, Lombardo, Antonio, Watanabe, Kenji, Taniguchi, Takashi, Bonn, Mischa, Turchinovich, Dmitry, Stampfer, Christoph, Ferrari, Andrea C, Cerullo, Giulio, Polini, Marco, and Koppens, Frank HL
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7. Clean energy - Abstract
Van der Waals heterostructures have emerged as promising building blocks that offer access to new physics, novel device functionalities and superior electrical and optoelectronic properties 1-7 . Applications such as thermal management, photodetection, light emission, data communication, high-speed electronics and light harvesting 8-16 require a thorough understanding of (nanoscale) heat flow. Here, using time-resolved photocurrent measurements, we identify an efficient out-of-plane energy transfer channel, where charge carriers in graphene couple to hyperbolic phonon polaritons 17-19 in the encapsulating layered material. This hyperbolic cooling is particularly efficient, giving picosecond cooling times for hexagonal BN, where the high-momentum hyperbolic phonon polaritons enable efficient near-field energy transfer. We study this heat transfer mechanism using distinct control knobs to vary carrier density and lattice temperature, and find excellent agreement with theory without any adjustable parameters. These insights may lead to the ability to control heat flow in van der Waals heterostructures.
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