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25 results on '"Carrega, Matteo"'

1. From Dyson Models to Many-Body Quantum Chaos

Author

Andreanov, Alexei, Carrega, Matteo, Murugan, Jeff, Olle, Jan, Rosa, Dario, Shir, Ruth, Andreanov, Alexei, Carrega, Matteo, Murugan, Jeff, Olle, Jan, Rosa, Dario, and Shir, Ruth

Abstract

Understanding the mechanisms underlying many-body quantum chaos is one of the big challenges in theoretical physics. We tackle this problem by considering a set of perturbed quadratic Sachdev-Ye-Kitaev (SYK) Hamiltonians defined on graphs. This allows to disambiguate between operator growth and \emph{delocalization}, showing that the latter is the dominant process in the single-particle to many-body chaotic transition. Our results are verified numerically with state-of-the-art numerical techniques, capable of extracting eigenvalues in a desired energy window of very large Hamiltonians, in this case up to dimension $2^{19}\times 2^{19}$. Our approach essentially provides a new way of viewing many-body chaos from a single-particle perspective., Comment: 5 + 1 pages, 4 + 1 figures

Published
2023

2. Unveiling operator growth in SYK quench dynamics

Author

Carrega, Matteo, Kim, Joonho, Rosa, Dario, Carrega, Matteo, Kim, Joonho, and Rosa, Dario

Abstract

We study non-equilibrium dynamics induced by a sudden quench of strongly correlated Hamiltonians with all-to-all interactions. By relying on a Sachdev-Ye-Kitaev (SYK) based quench protocol, we show that the time evolution of simple spin-spin correlation functions is highly sensitive to the degree of locality of the corresponding operators, once an appropriate set of fundamental fields is identified. By tracking the time-evolution of specific spin-spin correlation functions and their decay, we argue that it is possible to distinguish between operator hopping and operator growth dynamics; the latter being a hallmark of quantum chaos in many-body quantum systems. Such observation, in turn, could constitute a promising tool to probe the emergence of chaotic behavior, rather accessible in state-of-the-art quench setups., Comment: v2: Fixed broken Unicode characters; REVTeX4-1, 13 pages, 14 figures

Published
2020
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3. Ultra-stable charging of fast-scrambling SYK quantum batteries

Author

Rosa, Dario, Rossini, Davide, Andolina, Gian Marcello, Polini, Marco, Carrega, Matteo, Rosa, Dario, Rossini, Davide, Andolina, Gian Marcello, Polini, Marco, and Carrega, Matteo

Abstract

Collective behavior strongly influences the charging dynamics of quantum batteries (QBs). Here, we study the impact of nonlocal correlations on the energy stored in a system of $N$ QBs. A unitary charging protocol based on a Sachdev-Ye-Kitaev (SYK) quench Hamiltonian is thus introduced and analyzed. SYK models describe strongly interacting systems with nonlocal correlations and fast thermalization properties. Here, we demonstrate that, once charged, the average energy stored in the QB is very stable, realizing an ultraprecise charging protocol. By studying fluctuations of the average energy stored, we show that temporal fluctuations are strongly suppressed by the presence of nonlocal correlations at all time scales. A comparison with other paradigmatic examples of many-body QBs shows that this is linked to the collective dynamics of the SYK model and its high level of entanglement. We argue that such feature relies on the fast scrambling property of the SYK Hamiltonian, and on its fast thermalization properties, promoting this as an ideal model for the ultimate temporal stability of a generic QB. Finally, we show that the temporal evolution of the ergotropy, a quantity that characterizes the amount of extractable work from a QB, can be a useful probe to infer the thermalization properties of a many-body quantum system., Comment: 13 pages, 11 figures; v2: references added; a new section discussing the role of quantum chaos added; version to appear on JHEP

Published
2019
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4. Ultra-stable charging of fast-scrambling SYK quantum batteries

Author

Rosa, Dario, Rossini, Davide, Andolina, Gian Marcello, Polini, Marco, Carrega, Matteo, Rosa, Dario, Rossini, Davide, Andolina, Gian Marcello, Polini, Marco, and Carrega, Matteo

Abstract

Collective behavior strongly influences the charging dynamics of quantum batteries (QBs). Here, we study the impact of nonlocal correlations on the energy stored in a system of $N$ QBs. A unitary charging protocol based on a Sachdev-Ye-Kitaev (SYK) quench Hamiltonian is thus introduced and analyzed. SYK models describe strongly interacting systems with nonlocal correlations and fast thermalization properties. Here, we demonstrate that, once charged, the average energy stored in the QB is very stable, realizing an ultraprecise charging protocol. By studying fluctuations of the average energy stored, we show that temporal fluctuations are strongly suppressed by the presence of nonlocal correlations at all time scales. A comparison with other paradigmatic examples of many-body QBs shows that this is linked to the collective dynamics of the SYK model and its high level of entanglement. We argue that such feature relies on the fast scrambling property of the SYK Hamiltonian, and on its fast thermalization properties, promoting this as an ideal model for the ultimate temporal stability of a generic QB. Finally, we show that the temporal evolution of the ergotropy, a quantity that characterizes the amount of extractable work from a QB, can be a useful probe to infer the thermalization properties of a many-body quantum system., Comment: 13 pages, 11 figures; v2: references added; a new section discussing the role of quantum chaos added; version to appear on JHEP

Published
2019
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5. Universal scaling of quench-induced correlations in a one-dimensional channel at finite temperature

Author

Calzona, Alessio, Gambetta, Filippo Maria, Carrega, Matteo, Cavaliere, Fabio, Schmidt, Thomas, Sassetti, Maura, Calzona, Alessio, Gambetta, Filippo Maria, Carrega, Matteo, Cavaliere, Fabio, Schmidt, Thomas, and Sassetti, Maura

Abstract

It has been shown that a quantum quench of interactions in a one-dimensional fermion system at zero temperature induces a universal power law ∝t−2 in its long-time dynamics. In this paper we demonstrate that this behaviour is robust even in the presence of thermal effects. The system is initially prepared in a thermal state, then at a given time the bath is disconnected and the interaction strength is suddenly quenched. The corresponding effects on the long times dynamics of the non-equilibrium fermionic spectral function are considered. We show that the non-universal power laws, present at zero temperature, acquire an exponential decay due to thermal effects and are washed out at long times, while the universal behaviour ∝t−2 is always present. To verify our findings, we argue that these features are also visible in transport properties at finite temperature. The long-time dynamics of the current injected from a biased probe exhibits the same universal power law relaxation, in sharp contrast with the non-quenched case which features a fast exponential decay of the current towards its steady value, and thus represents a fingerprint of quench-induced dynamics. Finally, we show that a proper tuning of the probe temperature, compared to that of the one-dimensional channel, can enhance the visibility of the universal power-law behaviour.

Published
2018
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6. Asymmetries in the spectral density of an interaction-quenched Luttinger liquid

Author

Calzona, Alessio, Gambetta, Filippo Maria, Carrega, Matteo, Cavaliere, Fabio, Sassetti, Maura, Calzona, Alessio, Gambetta, Filippo Maria, Carrega, Matteo, Cavaliere, Fabio, and Sassetti, Maura

Abstract

The spectral density of an interaction-quenched one-dimensional system is investigated. Both direct and inverse quench protocols are considered and it is found that the former leads to stronger effects on the spectral density with respect to the latter. Such asymmetry is directly reflected on transport properties of the system, namely the charge and energy current flowing to the system from a tunnel coupled biased probe. In particular, the injection of particles from the probe to the right-moving channel of the system is considered. The resulting fractionalization phenomena are strongly affected by the quench protocol and display asymmetries in the case of direct and inverse quench. Transport properties therefore emerge as natural probes for the observation of this quench-induced behavior.

Published
2018
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7. Universal scaling of quench-induced correlations in a one-dimensional channel at finite temperature

Author

Calzona, Alessio, Gambetta, Filippo Maria, Carrega, Matteo, Cavaliere, Fabio, Schmidt, Thomas, Sassetti, Maura, Calzona, Alessio, Gambetta, Filippo Maria, Carrega, Matteo, Cavaliere, Fabio, Schmidt, Thomas, and Sassetti, Maura

Abstract

It has been shown that a quantum quench of interactions in a one-dimensional fermion system at zero temperature induces a universal power law ∝t−2 in its long-time dynamics. In this paper we demonstrate that this behaviour is robust even in the presence of thermal effects. The system is initially prepared in a thermal state, then at a given time the bath is disconnected and the interaction strength is suddenly quenched. The corresponding effects on the long times dynamics of the non-equilibrium fermionic spectral function are considered. We show that the non-universal power laws, present at zero temperature, acquire an exponential decay due to thermal effects and are washed out at long times, while the universal behaviour ∝t−2 is always present. To verify our findings, we argue that these features are also visible in transport properties at finite temperature. The long-time dynamics of the current injected from a biased probe exhibits the same universal power law relaxation, in sharp contrast with the non-quenched case which features a fast exponential decay of the current towards its steady value, and thus represents a fingerprint of quench-induced dynamics. Finally, we show that a proper tuning of the probe temperature, compared to that of the one-dimensional channel, can enhance the visibility of the universal power-law behaviour.

Published
2018
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8. Asymmetries in the spectral density of an interaction-quenched Luttinger liquid

Author

Calzona, Alessio, Gambetta, Filippo Maria, Carrega, Matteo, Cavaliere, Fabio, Sassetti, Maura, Calzona, Alessio, Gambetta, Filippo Maria, Carrega, Matteo, Cavaliere, Fabio, and Sassetti, Maura

Abstract

The spectral density of an interaction-quenched one-dimensional system is investigated. Both direct and inverse quench protocols are considered and it is found that the former leads to stronger effects on the spectral density with respect to the latter. Such asymmetry is directly reflected on transport properties of the system, namely the charge and energy current flowing to the system from a tunnel coupled biased probe. In particular, the injection of particles from the probe to the right-moving channel of the system is considered. The resulting fractionalization phenomena are strongly affected by the quench protocol and display asymmetries in the case of direct and inverse quench. Transport properties therefore emerge as natural probes for the observation of this quench-induced behavior.

Published
2018
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9. Nonequilibrium effects on charge and energy partitioning after an interaction quench

Author

MIUR-FIRB2013 – Project Coca (Grant No. RBFR1379UX) [sponsor], COST Action MP1209 [sponsor], Calzona, Alessio, Gambetta, Filippo Maria, Carrega, Matteo, Cavaliere, Fabio, Sassetti, Maura, MIUR-FIRB2013 – Project Coca (Grant No. RBFR1379UX) [sponsor], COST Action MP1209 [sponsor], Calzona, Alessio, Gambetta, Filippo Maria, Carrega, Matteo, Cavaliere, Fabio, and Sassetti, Maura

Abstract

Charge and energy fractionalization are among the most intriguing features of interacting one-dimensional fermion systems. In this work we determine how these phenomena are modified in the presence of an interaction quench. Charge and energy are injected into the system suddenly after the quench, by means of tunneling processes with a noninteracting one-dimensional probe. Here, we demonstrate that the system settles to a steady state in which the charge fractionalization ratio is unaffected by the prequenched parameters. On the contrary, due to the postquench nonequilibrium spectral function, the energy partitioning ratio is strongly modified, reaching values larger than 1. This is a peculiar feature of the nonequilibrium dynamics of the quench process and it is in sharp contrast with the nonquenched case, where the ratio is bounded by 1.

Published
2017

11. Transport Properties as a Tool to Study Universal Quench-induced Dynamics in 1D Systems

Author

Calzona, Alessio, Gambetta, Filippo Maria, Carrega, Matteo, Sassetti, Maura, Calzona, Alessio, Gambetta, Filippo Maria, Carrega, Matteo, and Sassetti, Maura

Abstract

The study of the relaxation process that follows a quantum quench in 1D systems still represents an open research field. Here we consider a sudden change of the interparticle interaction and we identify a peculiar correlator of the system whose behavior is directly and deeply affected by the quench-induced dynamics. Interestingly, it features a universal power-law decay in time. Unfortunately, such a universal decay, although present, turns out to be subleading in intrinsic properties of the system such as the non- equilibrium spectral function. We thus consider a tunnel coupling of the system with a biased tip in order to be able to study also transport properties, namely the charge and energy current flowing from the tip to the system after the quench. In these quantities the universal power-law emerges clearly, especially if one focuses on energy current and its fractionalization into a right- and left- moving components. In particular, we show that the presence of a transient in the energy fractionalization ratio is a direct hallmark of the quench-induced relaxation. Within the setup we have considered, time-dependent transport properties are thus promoted to useful and promising tools to access the mechanisms at the base of the out-of- equilibrium dynamics following quantum quench.

Published
2017

12. Fractionalization of charge and energy after electron injection in 1D helical systems

Author

Calzona, Alessio, Acciai, Matteo, Carrega, Matteo, Cavaliere, Fabio, Sassetti, Maura, Calzona, Alessio, Acciai, Matteo, Carrega, Matteo, Cavaliere, Fabio, and Sassetti, Maura

Abstract

The possibility to inject a single electron into ballistic 1D conductors is at the basis of the new and fast developing field of electron quantum optics. In this respect, helical edge states of topological insulators can be used as electronic waveguides and would be an ideal playground [1,2]. Here we thus study and characterize the tunneling of a single electron from a mesoscopic capacitor into a couple of interacting helical edge channels [3]. The injection process leads to the creation of a pair of fractional excitations travelling in opposite directions. Their charge and energy profiles are analyzed. We also show that the energy partitioning between the two fractional excitations depends both on the interaction strength and on the injection parameters. Interestingly, this allows for a situation in which energy and charge mainly flow in opposite directions. In addition, such peculiar behavior of energy partitioning suggests that it can be also used as a tool to probe features of out-of-equilibrium systems [4]. [1] G. Fève et al., Science 316, 1169 (2007) [2] D. Ferraro et al., PRB 89, 075407 (2014) [3] A. Calzona et al., PRB 94, 035404 (2016) [4] A. Calzona et al., arXiv:1610.04492

Published
2017

13. Quench-induced entanglement and relaxation dynamics in Luttinger liquids

Author

Calzona, Alessio(*), Gambetta, Filippo Maria(*), Cavaliere, Fabio, Carrega, Matteo, Sassetti, Maura, Calzona, Alessio(*), Gambetta, Filippo Maria(*), Cavaliere, Fabio, Carrega, Matteo, and Sassetti, Maura

Abstract

We investigate the time evolution towards the asymptotic steady state of a one-dimensional interacting system after a quantum quench. We show that at finite times the latter induces entanglement between right- and left-moving density excitations, encoded in their cross-correlators, which vanishes in the long-time limit. This behavior results in a universal time decay ∝t−2 of the system spectral properties, in addition to nonuniversal power-law contributions typical of Luttinger liquids. Importantly, we argue that the presence of quench-induced entanglement clearly emerges in transport properties, such as charge and energy currents injected in the system from a biased probe and determines their long-time dynamics. In particular, the energy fractionalization phenomenon turns out to be a promising platform to observe the universal power-law decay ∝t−2 induced by entanglement and represents a novel way to study the corresponding relaxation mechanism.

Published
2017

15. Fractionalization of charge and energy after electron injection in 1D helical systems

Author

Calzona, Alessio, Acciai, Matteo, Carrega, Matteo, Cavaliere, Fabio, Sassetti, Maura, Calzona, Alessio, Acciai, Matteo, Carrega, Matteo, Cavaliere, Fabio, and Sassetti, Maura

Abstract

The possibility to inject a single electron into ballistic 1D conductors is at the basis of the new and fast developing field of electron quantum optics. In this respect, helical edge states of topological insulators can be used as electronic waveguides and would be an ideal playground [1,2]. Here we thus study and characterize the tunneling of a single electron from a mesoscopic capacitor into a couple of interacting helical edge channels [3]. The injection process leads to the creation of a pair of fractional excitations travelling in opposite directions. Their charge and energy profiles are analyzed. We also show that the energy partitioning between the two fractional excitations depends both on the interaction strength and on the injection parameters. Interestingly, this allows for a situation in which energy and charge mainly flow in opposite directions. In addition, such peculiar behavior of energy partitioning suggests that it can be also used as a tool to probe features of out-of-equilibrium systems [4]. [1] G. Fève et al., Science 316, 1169 (2007) [2] D. Ferraro et al., PRB 89, 075407 (2014) [3] A. Calzona et al., PRB 94, 035404 (2016) [4] A. Calzona et al., arXiv:1610.04492

Published
2017

16. Quench-induced entanglement and relaxation dynamics in Luttinger liquids

Author

Calzona, Alessio(*), Gambetta, Filippo Maria(*), Cavaliere, Fabio, Carrega, Matteo, Sassetti, Maura, Calzona, Alessio(*), Gambetta, Filippo Maria(*), Cavaliere, Fabio, Carrega, Matteo, and Sassetti, Maura

Abstract

We investigate the time evolution towards the asymptotic steady state of a one-dimensional interacting system after a quantum quench. We show that at finite times the latter induces entanglement between right- and left-moving density excitations, encoded in their cross-correlators, which vanishes in the long-time limit. This behavior results in a universal time decay ∝t−2 of the system spectral properties, in addition to nonuniversal power-law contributions typical of Luttinger liquids. Importantly, we argue that the presence of quench-induced entanglement clearly emerges in transport properties, such as charge and energy currents injected in the system from a biased probe and determines their long-time dynamics. In particular, the energy fractionalization phenomenon turns out to be a promising platform to observe the universal power-law decay ∝t−2 induced by entanglement and represents a novel way to study the corresponding relaxation mechanism.

Published
2017

17. Transport Properties as a Tool to Study Universal Quench-induced Dynamics in 1D Systems

Author

Calzona, Alessio, Gambetta, Filippo Maria, Carrega, Matteo, Sassetti, Maura, Calzona, Alessio, Gambetta, Filippo Maria, Carrega, Matteo, and Sassetti, Maura

Abstract

The study of the relaxation process that follows a quantum quench in 1D systems still represents an open research field. Here we consider a sudden change of the interparticle interaction and we identify a peculiar correlator of the system whose behavior is directly and deeply affected by the quench-induced dynamics. Interestingly, it features a universal power-law decay in time. Unfortunately, such a universal decay, although present, turns out to be subleading in intrinsic properties of the system such as the non- equilibrium spectral function. We thus consider a tunnel coupling of the system with a biased tip in order to be able to study also transport properties, namely the charge and energy current flowing from the tip to the system after the quench. In these quantities the universal power-law emerges clearly, especially if one focuses on energy current and its fractionalization into a right- and left- moving components. In particular, we show that the presence of a transient in the energy fractionalization ratio is a direct hallmark of the quench-induced relaxation. Within the setup we have considered, time-dependent transport properties are thus promoted to useful and promising tools to access the mechanisms at the base of the out-of- equilibrium dynamics following quantum quench.

Published
2017

18. Nonequilibrium effects on charge and energy partitioning after an interaction quench

Author

MIUR-FIRB2013 – Project Coca (Grant No. RBFR1379UX) [sponsor], COST Action MP1209 [sponsor], Calzona, Alessio, Gambetta, Filippo Maria, Carrega, Matteo, Cavaliere, Fabio, Sassetti, Maura, MIUR-FIRB2013 – Project Coca (Grant No. RBFR1379UX) [sponsor], COST Action MP1209 [sponsor], Calzona, Alessio, Gambetta, Filippo Maria, Carrega, Matteo, Cavaliere, Fabio, and Sassetti, Maura

Abstract

Charge and energy fractionalization are among the most intriguing features of interacting one-dimensional fermion systems. In this work we determine how these phenomena are modified in the presence of an interaction quench. Charge and energy are injected into the system suddenly after the quench, by means of tunneling processes with a noninteracting one-dimensional probe. Here, we demonstrate that the system settles to a steady state in which the charge fractionalization ratio is unaffected by the prequenched parameters. On the contrary, due to the postquench nonequilibrium spectral function, the energy partitioning ratio is strongly modified, reaching values larger than 1. This is a peculiar feature of the nonequilibrium dynamics of the quench process and it is in sharp contrast with the nonquenched case, where the ratio is bounded by 1.

Published
2017

20. Time-resolved energy dynamics after single electron injection into an interacting helical liquid

Author

Calzona, Alessio, Acciai, Matteo, Carrega, Matteo, Cavaliere, Fabio, Sassetti, Maura, Calzona, Alessio, Acciai, Matteo, Carrega, Matteo, Cavaliere, Fabio, and Sassetti, Maura

Abstract

The possibility of injecting a single electron into ballistic conductors is at the basis of the new field of electron quantum optics. Here, we consider a single electron injection into the helical edge channels of a topological insulator. Their counterpropagating nature and the unavoidable presence of electron-electron interactions dramatically affect the time evolution of the single wave packet. Modeling the injection process from a mesoscopic capacitor in the presence of nonlocal tunneling, we focus on the time-resolved charge and energy packet dynamics. Both quantities split up into counterpropagating contributions whose profiles are strongly affected by the interaction strength. In addition, stronger signatures are found for the injected energy, which is also affected by the finite width of the tunneling region, in contrast to what happens for the charge. Indeed, the energy flow can be controlled by tuning the injection parameters, and we demonstrate that, in the presence of nonlocal tunneling, it is possible to achieve a situation in which charge and energy flow in opposite directions.

Published
2016

21. Time-resolved energy dynamics after single electron injection into an interacting helical liquid

Author

Calzona, Alessio, Acciai, Matteo, Carrega, Matteo, Cavaliere, Fabio, Sassetti, Maura, Calzona, Alessio, Acciai, Matteo, Carrega, Matteo, Cavaliere, Fabio, and Sassetti, Maura

Abstract

The possibility of injecting a single electron into ballistic conductors is at the basis of the new field of electron quantum optics. Here, we consider a single electron injection into the helical edge channels of a topological insulator. Their counterpropagating nature and the unavoidable presence of electron-electron interactions dramatically affect the time evolution of the single wave packet. Modeling the injection process from a mesoscopic capacitor in the presence of nonlocal tunneling, we focus on the time-resolved charge and energy packet dynamics. Both quantities split up into counterpropagating contributions whose profiles are strongly affected by the interaction strength. In addition, stronger signatures are found for the injected energy, which is also affected by the finite width of the tunneling region, in contrast to what happens for the charge. Indeed, the energy flow can be controlled by tuning the injection parameters, and we demonstrate that, in the presence of nonlocal tunneling, it is possible to achieve a situation in which charge and energy flow in opposite directions.

Published
2016

25. Highly confined low-loss plasmons in graphene–boron nitride heterostructures

Author

Universitat Politècnica de Catalunya. Institut de Ciències Fotòniques, Woessner, Achim, Lundeberg, Mark B., Gao, Yuanda, Principi, Alessandro, Alonso-González, Pablo, Carrega, Matteo, Watanabe, Kenji, Taniguchi, Takashi, Vignale, Giovanni, Polini, Marco, Hone, James, Hillenbrand, Rainer, Koppens, Frank H. L., Universitat Politècnica de Catalunya. Institut de Ciències Fotòniques, Woessner, Achim, Lundeberg, Mark B., Gao, Yuanda, Principi, Alessandro, Alonso-González, Pablo, Carrega, Matteo, Watanabe, Kenji, Taniguchi, Takashi, Vignale, Giovanni, Polini, Marco, Hone, James, Hillenbrand, Rainer, and Koppens, Frank H. L.

Abstract

Graphene plasmons were predicted to possess simultaneous ultrastrong field confinement and very low damping, enabling new classes of devices for deep-subwavelength metamaterials, single-photon nonlinearities, extraordinarily strong light–matter interactions and nano-optoelectronic switches. Although all of these great prospects require low damping, thus far strong plasmon damping has been observed, with both impurity scattering and many-body effects in graphene proposed as possible explanations. With the advent of van der Waals heterostructures, new methods have been developed to integrate graphene with other atomically flat materials. In this Article we exploit near-field microscopy to image propagating plasmons in high-quality graphene encapsulated between two films of hexagonal ​boron nitride (h-BN). We determine the dispersion and plasmon damping in real space. We find unprecedentedly low plasmon damping combined with strong field confinement and confirm the high uniformity of this plasmonic medium. The main damping channels are attributed to intrinsic thermal phonons in the graphene and dielectric losses in the h-BN. The observation and in-depth understanding of low plasmon damping is the key to the development of graphene nanophotonic and nano-optoelectronic devices., Peer Reviewed, Postprint (author’s final draft)

Published
2014

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