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1. Polaron formation in insulators and the key role of hole scattering processes: Band insulators, charge density waves and Mott transition

Author

Amelio, Ivan, Mazza, Giacomo, and Goldman, Nathan

Subjects
Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Quantum Gases, Quantum Physics
Abstract

A mobile impurity immersed in a non-interacting Fermi sea is dressed by the gapless particle-hole excitations of the fermionic medium. This conventional Fermi-polaron setting is well described by the so-called ladder approximation, which consists in neglecting impurity-hole scattering processes. In this work, we analyze polaron formation in the context of insulating states of matter, considering increasing levels of correlation in the medium:~band insulators originating from external periodic potentials, spontaneously-formed charge density waves, and a Fermi-Hubbard system undergoing a metal-Mott insulator transition. The polaron spectral function is shown to exhibit striking signatures of the underlying fermionic background, such as the single-particle band gap, particle-hole symmetry and the transition to the Mott state. These signatures are identified within the framework of the Chevy ansatz, i.e. upon restricting the Hilbert space to single particle-hole excitations. Interestingly, we find that the ladder approximation is inaccurate in these band systems, due to the fact that the particle and hole scattering phase spaces are comparable. Our results provide a step forward in the understanding of polaron formation in correlated many-body media, which are relevant to both cold-atom and semiconductor experiments., Comment: 14 pages, 7 figures

Published
2024

2. Collective entanglement in quantum materials with competing orders

Author

Mazza, Giacomo and Budroni, Costantino

Subjects
Condensed Matter - Strongly Correlated Electrons, Quantum Physics
Abstract

We investigate entanglement detection in quantum materials through criteria based on the simultaneous suppression of collective matter excitations. Unlike other detection schemes, these criteria can be applied to continuous and unbounded variables. By considering a system of interacting dipoles on a lattice, we show the detection of collective entanglement arising from two different physical mechanisms, namely, the ferroelectric ordering and the dressing of matter degrees of freedom by light. In the latter case, the detection shows the formation of a collective entangled phase not directly related to spontaneous symmetry breaking. These results open a new perspective for the entanglement characterization of competing orders in quantum materials, and have direct application to quantum paraelectrics with large polariton splittings., Comment: 5 pages, 3 figures

Published
2024

3. Tuning Fermi Liquids with Sub-wavelength Cavities

Author

Riolo, Riccardo, Tomadin, Andrea, Mazza, Giacomo, Asgari, Reza, MacDonald, Allan H., and Polini, Marco

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

The question of whether or not passive sub-wavelength cavities can alter the properties of quantum materials is currently attracting a great deal of attention. In this Letter we show that the Fermi liquid parameters of a two-dimensional metal are modified by cavity polariton modes, and that these changes can be monitored by measuring a paradigmatic magneto-transport phenomenon, Shubnikov-de Haas oscillations in a weak perpendicular magnetic field. This effect is intrinsic, and totally unrelated to disorder. As an illustrative example, we carry out explicit calculations of the Fermi liquid parameters of graphene in a planar van der Waals cavity formed by natural hyperbolic crystals and metal gates.

Published
2024

4. Hidden excitonic quantum states with broken time-reversal symmetry

Author

Mazza, Giacomo and Polini, Marco

Subjects
Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Superconductivity
Abstract

The spontaneous breaking of time-reversal symmetry due to purely-orbital mechanisms (i.e.~not involving spin degrees of freedom) yields extremely exotic phases of matter such as Chern insulators and chiral superconductors. In this Letter, we show that excitonic insulators, by exploiting the transition from the excitonic ground state to a purely-orbital time reversal symmetry broken hidden state, can realize another notable example of this class. The transition to the hidden state is controlled by engineered geometrical constraints which enable the coupling between the excitonic order parameter and the free-space electromagnetic field. These results pave the way towards exotic orbital magnetic order in quantum materials and are also relevant for disentangling excitonic phase transitions from trivial structural ones., Comment: 5 pages, 4 figures

Published
2023
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5. Strongly correlated exciton-polarons in twisted homo-bilayer heterostructures

Author

Mazza, Giacomo and Amaricci, Adriano

Subjects
Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Quantum Gases
Abstract

We consider dressing of excitonic properties by strongly correlated electrons in gate controlled twisted homo-bilayer heterostructures. The combined effect of the moir\'e potential and the Coulomb interaction supports the formation of different strongly correlated phases depending on the filling, including charge-ordered metals or incompressible insulators at integer occupation. The coupling between excitons and electrons results in a splitting of the excitonic resonance into an attractive and a repulsive polaron peak. Analyzing the properties of the exciton-polarons across the different phases of the system, we reveal a discontinuous evolution of the spectrum with the formation of a double-peak structure in the repulsive polaron branch. The double-peak structure emerges for non-integer fillings and it is controlled by the energy separation between the quasi-particle states close to the Fermi level and the high-energy doublons excitations. Our results demonstrate that exciton-polarons carry a clear hallmark of the electronic correlations and, thus, provide a direct signature of the formation of correlation driven insulators in gate controlled heterostructures., Comment: published version, 7 pages, 4 figures

Published
2022
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6. Dissipative Dynamics of a Fermionic Superfluid with Two-Body Losses

Author

Mazza, Giacomo and Schirò, Marco

Subjects
Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Quantum Gases, Condensed Matter - Superconductivity
Abstract

We study the dissipative dynamics of a fermionic superfluid in presence of two-body losses. We use a variational approach for the Lindblad dynamics and obtain dynamical equations for Anderson's pseudo-spins where dissipation enters as a complex pairing interaction as well as effective, density-dependent, single particle losses which break the conservation of the pseudo-spin norm. We show that this latter has key consequences on the dynamical behavior of the system. In the case of a sudden switching of two-body losses we show that the superfluid order parameter decays much faster than then particle density at short times and eventually slows-down, setting into a power-law decay at longer time scales driven by the depletion of the system. We then consider a quench of pairing interaction, leading to coherent oscillations in the unitary case, followed by the switching of the dissipation. We show that losses wash away the dynamical BCS synchronization by introducing not only damping but also a renormalization of the frequency of coherent oscillations, which depends non-linearly from the rate of the two-body losses., Comment: 5 pages, 3 figures. Supplementary Material: 6 pages, 3 figures

Published
2022
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7. Optical dressing of the electronic response of two-dimensional semiconductors in quantum and classical descriptions of cavity electrodynamics

Author

Amelio, Ivan, Korosec, Lukas, Carusotto, Iacopo, and Mazza, Giacomo

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics
Abstract

We study quantum effects of the vacuum light-matter interaction in materials embedded in optical cavities. We focus on the electronic response of a two-dimensional semiconductor placed inside a planar cavity. By using a diagrammatic expansion of the electron-photon interaction, we describe signatures of light-matter hybridization characterized by large asymmetric shifts of the spectral weight at resonant frequencies. We follow the evolution of the light-dressing from the cavity to the free-space limit. In the cavity limit, light-matter hybridization results in a modification of the optical gap with sizeable spectral weight appearing below the bare gap edge. In the limit of large cavities, we find a residual redistribution of spectral weight which becomes independent of the distance between the two mirrors. We show that the photon dressing of the electronic response can be fully explained by using a classical description of light. The classical description is found to hold up to a strong coupling regime of the light-matter interaction highlighted by the large modification of the photon spectra with respect to the empty cavity. We show that, despite the strong coupling, quantum corrections are negligibly small and weakly dependent on the cavity confinement. As a consequence, in contrast to the optical gap, the single particle electronic band gap is not sensibly modified by the strong-coupling. Our results show that quantum corrections are dominated by off-resonant photon modes at high energy. As such, cavity confinement can hardly be seen as a knob to control the quantum effects of the light-matter interaction in vacuum., Comment: 14 pages, 9 figures

Published
2021
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8. Common microscopic origin of the phase transitions in Ta$_2$NiS$_5$ and the excitonic insulator candidate Ta$_2$NiSe$_5$

Author

Windgätter, Lukas, Rösner, Malte, Mazza, Giacomo, Hübener, Hannes, Georges, Antoine, Millis, Andrew J., Latini, Simone, and Rubio, Angel

Subjects
Condensed Matter - Materials Science
Abstract

The structural phase transition in Ta$_2$NiSe$_5$ has been envisioned as driven by the formation of an excitonic insulating phase. However, the role of structural and electronic instabilities on crystal symmetry breaking has yet to be disentangled. Meanwhile, the phase transition in its complementary material Ta$_2$NiS$_5$ does not show any experimental hints of an excitonic insulating phase. We present a microscopic investigation of the electronic and phononic effects involved in the structural phase transition in Ta$_2$NiSe$_5$ and Ta$_2$NiS$_5$ using extensive first-principles calculations. In both materials the crystal symmetries are broken by phonon instabilities, which in turn lead to changes in the electronic bandstructure also observed in experiment. A total energy landscape analysis shows no tendency towards a purely electronic instability and we find that a sizeable lattice distortion is needed to open a bandgap. We conclude that an excitonic instability is not needed to explain the phase transition in both Ta$_2$NiSe$_5$ and Ta$_2$NiS$_5$.

Published
2021

9. Thermal dynamics and electronic temperature waves in layered correlated materials

Author

Mazza, Giacomo, Gandolfi, Marco, Capone, Massimo, Banfi, Francesco, and Giannetti, Claudio

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

We explore layered strongly correlated materials as a platform to identify and control unconventional heat transfer phenomena. We demonstrate that these systems can be tailored to sustain a wide spectrum of heat transport regimes, ranging from ballistic, to hydrodynamic all the way to diffusive. Within the hydrodynamic regime, wave-like temperature oscillations are predicted up to room temperature. All the above phenomena have a purely electronic origin, stemming from the existence of two components in the electronic system, each one thermalized at different temperatures. The interaction strength can be exploited as a knob to control the different thermal transport regimes. The present results pave the way to transition-metal oxide heterostructures as building blocks for nanodevices exploiting the wave-like nature of heat transfer on the picosecond time scale., Comment: 12 pages and 6 figures + Supplementary Information

Published
2021
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10. Interface and bulk superconductivity in superconducting heterostructures with enhanced critical temperatures

Author

Mazza, Giacomo, Amaricci, Adriano, and Capone, Massimo

Subjects
Condensed Matter - Superconductivity, Condensed Matter - Strongly Correlated Electrons
Abstract

We consider heterostructures obtained by stacking layers of two s-wave superconductors with significantly different coupling strengths, respectively in the weak- and strong-coupling regimes. The weak- and strong-coupling superconductors are chosen with similar critical temperatures for bulk systems. Using dynamical mean-field theory methods, we find an ubiquitous enhancement of the superconducting critical temperature for all the heterostructures where a single layer of one of the two superconductors is alternated with a thicker multilayer of the other. Two distinct physical regimes can be identified as a function of the thickness of the larger layer: (i) an inherently inhomogeneous superconductor characterized by the properties of the two isolated bulk superconductors where the enhancement of the critical temperature is confined to the interface and (ii) a bulk superconductor with an enhanced critical temperature extending to the whole heterostructure. We characterize the crossover between these regimes in terms of the competition between two length scales connected with the proximity effect and the pair coherence., Comment: 7 pages, 4 figures

Published
2020
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11. Electromagnetic coupling in tight-binding models for strongly correlated light and matter

Author

Li, Jiajun, Golez, Denis, Mazza, Giacomo, Millis, Andrew, Georges, Antoine, and Eckstein, Martin

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

We discuss the construction of low-energy tight-binding Hamiltonians for condensed matter systems with a strong coupling to the quantum electromagnetic field. Such Hamiltonians can be obtained by projecting the continuum theory on a given set of Wannier orbitals. However, different representations of the continuum theory lead to different low-energy formulations, because different representations may entangle light and matter, transforming orbitals into light-matter hybrid states before the projection. In particular, a multi-center Power-Zienau-Woolley transformation yields a dipolar Hamiltonian which incorporates the light-matter coupling via both Peierls phases and a polarization density. We compare this dipolar gauge Hamiltonian and the straightforward Coulomb gauge Hamiltonian for a one-dimensional solid, to describe sub-cycle light-driven electronic motion in the semiclassical limit, and a coupling of the solid to a quantized cavity mode which renormalizes the band-structure into electron-polariton bands. Both descriptions yield the same result when many bands are taken into account, but the dipolar Hamiltonian is more accurate when the model is restricted to few electronic bands, while the Coulomb Hamiltonian requires fewer electromagnetic modes.

Published
2020
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12. Nature of symmetry breaking at the excitonic insulator transition: Ta$_2$NiSe$_5$

Author

Mazza, Giacomo, Rösner, Malte, Windgätter, Lukas, Latini, Simone, Hübener, Hannes, Millis, Andrew J., Rubio, Angel, and Georges, Antoine

Subjects
Condensed Matter - Materials Science
Abstract

Ta$_2$NiSe$_5$ is one of the most promising materials for hosting an excitonic insulator ground state. While a number of experimental observations have been interpreted in this way, the precise nature of the symmetry breaking occurring in Ta$_2$NiSe$_5$, the electronic order parameter, and a realistic microscopic description of the transition mechanism are, however, missing. By a symmetry analysis based on first-principles calculations, we uncover the \emph{discrete} lattice symmetries which are broken at the transition. We identify a purely electronic order parameter of excitonic nature that breaks these discrete crystal symmetries and contributes to the experimentally observed lattice distortion from an orthorombic to a monoclinic phase. Our results provide a theoretical framework to understand and analyze the excitonic transition in Ta$_2$NiSe$_5$ and settle the fundamental questions about symmetry breaking governing the spontaneous formation of excitonic insulating phases in solid-state materials.

Published
2019
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13. Superradiant Quantum Materials

Author

Mazza, Giacomo and Georges, Antoine

Subjects
Condensed Matter - Strongly Correlated Electrons, Quantum Physics
Abstract

There is currently great interest in the strong coupling between the quantized photon field of a cavity and electronic or other degrees of freedom in materials. A major goal is the creation of novel collective states entangling photons with those degrees of freedom. Here we show that the cooperative effect between strong electron interactions in quantum materials and the long-range correlations induced by the photon field leads to the stabilization of coherent phases of light and matter. By studying a two-band model of interacting electrons coupled to a cavity field, we show that a phase characterized by the simultaneous condensation of excitons and photon superradiance can be realized, hence stabilizing and intertwining two collective phenomena which are rather elusive in the absence of this cooperative effect., Comment: 5 pages, 4 figures

Published
2018
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14. From sudden quench to adiabatic dynamics in the attractive Hubbard model

Author

Mazza, Giacomo

Subjects
Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Statistical Mechanics, Condensed Matter - Superconductivity
Abstract

We study the crossover between the sudden quench limit and the adiabatic dynamics of superconducting states in the attractive Hubbard model. We focus on the dynamics induced by the change of the attractive interaction during a finite ramp time which is varied in order to track the evolution of the dynamical phase diagram from the sudden quench to the equilibrium limit. Two different dynamical regimes are realized for quenches towards weak and strong coupling interactions. At weak coupling the dynamics depends only on the energy injected into the system, whereas a dynamics retaining memory of the initial state takes place at strong coupling. We show that this is related to a sharp transition between a weak and a strong coupling quench dynamical regime, which defines the boundaries beyond which a dynamics independent from the initial state is recovered. Comparing the dynamics in the superconducting and non-superconducting phases we argue that this is due to the lack of an adiabatic connection to the equilibrium ground state for non-equilibrium superconducting states in the strong coupling quench regime., Comment: 10 pages, 5 figures

Published
2017
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15. Non-equilibrium superconductivity in driven alkali-doped fullerides

Author

Mazza, Giacomo and Georges, Antoine

Subjects
Condensed Matter - Superconductivity, Condensed Matter - Strongly Correlated Electrons
Abstract

We investigate the formation of non-equilibrium superconducting states in driven alkali-doped fullerides A$_3$C$_{60}$. Within a minimal three-orbital model for the superconductivity of these materials, it was recently demonstrated theoretically that an orbital-dependent imbalance of the interactions leads to an enhancement of superconductivity at equilibrium [M. Kim et al. Phys. Rev. B 94, 155152 (2016)]. We investigate the dynamical response to a time periodic modulation of this interaction imbalance, and show that it leads to the formation of a transient superconducting state which survives much beyond the equilibrium critical temperature $T_c$. For a specific range of modulation frequencies, we find that the driving reduces superconductivity when applied to a superconducting state below $T_c$, while still inducing a superconducting state when the initial temperature is larger than $T_c$. These findings reinforce the relevance of the interaction-imbalance mechanism as a possible explanation of the recent experimental observation of light-induced superconductivity in alkali-doped fullerenes., Comment: 10 pages, 5 figures

Published
2017
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16. Dynamical quantum phase transitions and broken-symmetry edges in the many-body eigenvalue spectrum

Author

Mazza, Giacomo and Fabrizio, Michele

Subjects
Condensed Matter - Strongly Correlated Electrons, Quantum Physics
Abstract

Many body models undergoing a quantum phase transition to a broken-symmetry phase that survives up to a critical temperature must possess, in the ordered phase, symmetric as well as non-symmetric eigenstates. We predict, and explicitly show in the fully-connected Ising model in a transverse field, that these two classes of eigenstates do not overlap in energy, and therefore that an energy edge exists separating low-energy symmetry-breaking eigenstates from high-energy symmetry-invariant ones. This energy is actually responsible, as we show, for the dynamical phase transition displayed by this model under a sudden large increase of the transverse field. A second situation we consider is the opposite, where the symmetry-breaking eigenstates are those in the high-energy sector of the spectrum, whereas the low-energy eigenstates are symmetric. In that case too a special energy must exist marking the boundary and leading to unexpected out-of-equilibrium dynamical behavior. An example is the fermionic repulsive Hubbard model Hamiltonian H. Exploiting the trivial fact that the high energy spectrum of H is also the low energy one of -H, we conclude that the high energy eigenstates of the Hubbard model are superfluid. Simulating in a time-dependent Gutzwiller approximation the time evolution of a high energy BCS-like trial wave function, we show that a small superconducting order parameter will actually grow in spite of the repulsive nature of interaction., Comment: 9 pages, 7 figures

Published
2012
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19. Oxygen isotope effect in VO2

Author

Rischau, Carl Willem, primary, He, Xu, additional, Mazza, Giacomo, additional, Gariglio, Stefano, additional, Triscone, Jean-Marc, additional, Ghosez, Philippe, additional, and del Valle, Javier, additional

Published
2023
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20. A geometric path towards excitonic insulators with purely orbital time-reversal symmetry breaking

Author

Mazza, Giacomo and Polini, Marco

Subjects
Superconductivity (cond-mat.supr-con), Condensed Matter - Strongly Correlated Electrons, Strongly Correlated Electrons (cond-mat.str-el), Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Superconductivity, Mesoscale and Nanoscale Physics (cond-mat.mes-hall), FOS: Physical sciences
Abstract

Crystalline exciton insulators are elusive states of matter whose ground state is a charge-density symmetry-broken (CDSB) state. In such a state of matter, the electronic charge distribution has a symmetry that is different from the one of the underlaying crystal. An excitonic instability of purely electronic origin is therefore inevitably coupled to lattice degrees of freedom. However, an excitonic instability can also lead to an excited state displaying broken time-reversal symmetry and a persistent current. In this Letter we show a geometric path that lowers the barrier between the CDSB state and the time-reversal symmetry broken (TRSB) state. For systems in a cylindrical geometry, and for a critical cylinder radius, the magnetic flux sourced by the persistent current stabilizes the TRSB state. Our results pave the way for achieving exotic orbital magnetic order in quantum materials in a controlled fashion, and are relevant for the control of coupled structural and excitonic phase transitions., 5 pages, 4 figures

Published
2023

25. Profilo aromatico varietale delle uve Mavrud, Bouquet e Rubin

Author

Lanati Donato, Marchi Dora, Mazza Giacomo, Baicheva Desislava, and La Rosa Alberto

Subjects
Microbiology, QR1-502, Physiology, QP1-981, Zoology, QL1-991
Abstract

Mediante gascromatografia accoppiata alla spettrometria di massa (GC/MS) è stato tracciato il profilo aromatico varietale delle uve Mavrud, Bouquet e Rubin e dei corrispondenti vini ottenuti dalle uve vinificate in purezza. Nelle uve sono stati identificati 33 composti appartenenti alla classe dei benzenoidi, dei terpeni e dei norisoprenoidi; tra i composti più interessanti sono stati trovati il cis e trans-8-OH-linalolo, il p-ment-1-ene-7,8-diolo, il 3-OH-β-damascone, il 3-oxo-α-ionolo, il grassopperchetone e il vomifoliolo. Nelle frazioni volatili libere dei vini sono stati identificati circa 60 composti, per la gran parte composti di fermentazione quali esteri, acetati, alcoli, benzenoidi e lattoni, oltre a terpeni e norisoprenoidi varietali. Nella frazione legata dei vini, ottenuta dopo idrolisi enzimatica sono stati trovati 30 composti varietali.

Published
2017
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26. Nature of symmetry breaking at the excitonic insulator transition: Ta2NiSe 5

Author

Mazza, Giacomo, Rösner, Malte, Windgätter, Lukas, Latini, Simone, Hübener, Hannes, Millis, Andrew J., Rubio, Angel, Georges, Antoine, European Commission, Department of Energy (US), European Research Council, Swiss National Science Foundation, Alexander von Humboldt Foundation, and Simons Foundation

Abstract

Ta2NiSe5 is one of the most promising materials for hosting an excitonic insulator ground state. While a number of experimental observations have been interpreted in this way, the precise nature of the symmetry breaking occurring in Ta2NiSe5, the electronic order parameter, and a realistic microscopic description of the transition mechanism are, however, missing. By a symmetry analysis based on first-principles calculations, we uncover the discrete lattice symmetries which are broken at the transition. We identify a purely electronic order parameter of excitonic nature that breaks these discrete crystal symmetries and contributes to the experimentally observed lattice distortion from an orthorombic to a monoclinic phase. Our results provide a theoretical framework to understand and analyze the excitonic transition in Ta2NiSe5 and settle the fundamental questions about symmetry breaking governing the spontaneous formation of excitonic insulating phases in solid-state materials., This work was supported by (A. G., G. M.) the European Research Council (ERC-319286-QMAC) and (A. M.) the US Department of Energy under Grant No. DE-SC 0019443. G. M. acknowledges support from the Swiss National Science Foundation Ambizione Grant No. PZ00P2_186146. S. L., L. W., H. H., and A. R. were supported by the European Research Council (Grant No. ERC-2015-AdG694097), the Cluster of Excellence AIM, Grupos Consolidados (Grant No. IT1249-19) and SFB925. S. L. acknowledges support from the Alexander von Humboldt foundation. The Flatiron Institute is a division of the Simons Foundation.

Published
2020

27. Nature of symmetry breaking at the excitonic insulator transition: Ta2NiSe 5

Author

European Commission, Department of Energy (US), European Research Council, Swiss National Science Foundation, Alexander von Humboldt Foundation, Simons Foundation, Mazza, Giacomo, Rösner, Malte, Windgätter, Lukas, Latini, Simone, Hübener, Hannes, Millis, Andrew J., Rubio, Angel, Georges, Antoine, European Commission, Department of Energy (US), European Research Council, Swiss National Science Foundation, Alexander von Humboldt Foundation, Simons Foundation, Mazza, Giacomo, Rösner, Malte, Windgätter, Lukas, Latini, Simone, Hübener, Hannes, Millis, Andrew J., Rubio, Angel, and Georges, Antoine

Abstract

Ta2NiSe5 is one of the most promising materials for hosting an excitonic insulator ground state. While a number of experimental observations have been interpreted in this way, the precise nature of the symmetry breaking occurring in Ta2NiSe5, the electronic order parameter, and a realistic microscopic description of the transition mechanism are, however, missing. By a symmetry analysis based on first-principles calculations, we uncover the discrete lattice symmetries which are broken at the transition. We identify a purely electronic order parameter of excitonic nature that breaks these discrete crystal symmetries and contributes to the experimentally observed lattice distortion from an orthorombic to a monoclinic phase. Our results provide a theoretical framework to understand and analyze the excitonic transition in Ta2NiSe5 and settle the fundamental questions about symmetry breaking governing the spontaneous formation of excitonic insulating phases in solid-state materials.

Published
2020

31. Common microscopic origin of the phase transitions in Ta2NiS5 and the excitonic insulator candidate Ta2NiSe5.

Author

Windgätter, Lukas, Rösner, Malte, Mazza, Giacomo, Hübener, Hannes, Georges, Antoine, Millis, Andrew J., Latini, Simone, and Rubio, Angel

Subjects
PHASE transitions, BAND gaps, CRYSTAL symmetry, PHONONS, MICROSCOPY
Abstract

The structural phase transition in Ta2NiSe5 has been envisioned as driven by the formation of an excitonic insulating phase. However, the role of structural and electronic instabilities on crystal symmetry breaking has yet to be disentangled. Meanwhile, the phase transition in its complementary material Ta2NiS5 does not show any experimental hints of an excitonic insulating phase. We present a microscopic investigation of the electronic and phononic effects involved in the structural phase transition in Ta2NiSe5 and Ta2NiS5 using extensive first-principles calculations. In both materials the crystal symmetries are broken by phonon instabilities, which in turn lead to changes in the electronic bandstructure also observed in the experiment. A total energy landscape analysis shows no tendency towards a purely electronic instability and we find that a sizeable lattice distortion is needed to open a bandgap. We conclude that an excitonic instability is not needed to explain the phase transition in both Ta2NiSe5 and Ta2NiS5. [ABSTRACT FROM AUTHOR]

Published
2021
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35. Non-Equilibrium Phenomena in Strongly Correlated Systems

Author

Mazza, Giacomo

Subjects
Non-equilibrium physics, dynamical phase transition, Dielectric breakdown in Mott insulators, Strongly correlated systems, Settore FIS/02 - Fisica Teorica, Modelli e Metodi Matematici
Published
2015

41. Nature of Symmetry Breaking at the Excitonic Insulator Transition: Ta2NiSe5.

Author

Mazza, Giacomo, Rösner, Malte, Windgätter, Lukas, Latini, Simone, Hübener, Hannes, Millis, Andrew J., Rubio, Angel, and Georges, Antoine

Subjects
*DISCRETE symmetries, *TANTALUM, *SYMMETRY, *CRYSTAL symmetry, *NATURE
Abstract

Ta2NiSe5 is one of the most promising materials for hosting an excitonic insulator ground state. While a number of experimental observations have been interpreted in this way, the precise nature of the symmetry breaking occurring in Ta2NiSe5, the electronic order parameter, and a realistic microscopic description of the transition mechanism are, however, missing. By a symmetry analysis based on first-principles calculations, we uncover the discrete lattice symmetries which are broken at the transition. We identify a purely electronic order parameter of excitonic nature that breaks these discrete crystal symmetries and contributes to the experimentally observed lattice distortion from an orthorombic to a monoclinic phase. Our results provide a theoretical framework to understand and analyze the excitonic transition in Ta2NiSe5 and settle the fundamental questions about symmetry breaking governing the spontaneous formation of excitonic insulating phases in solid-state materials. [ABSTRACT FROM AUTHOR]

Published
2020
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