Your search keyword '"Fève, G."' showing total 216 results

1. Quantum sensing of time dependent electromagnetic fields with single electron excitations

Author

Souquet-Basiège, H., Roussel, B., Rebora, G., Ménard, G., Safi, I., Fève, G., and Degiovanni, P.

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

In this study, we investigate the potential of electronic interferometers for probing the quantum state of electromagnetic radiation on a chip at sub-nanosecond time scales. We propose to use single electron excitations propagating within an electronic Mach-Zehnder interferometer in the Aharonov-Bohm dominated regime. We discuss how information about the quantum state of the electromagnetic radiation is encoded into the interference contribution to the average outgoing electrical current. By investigating squeezed radiation and single edge magnetoplasmons probed by Leviton pulses in a realistic setup, we show that single electron interferometers have the potential to probe quantum radiation in the time domain with sub-nanosecond to pico-second time resolution. Our research could have significant implications for probing the fundamental properties of light in the microwave to tera-Hertz domains at extremely short time scales., Comment: 31 pages, 15 figures

Published

2024

2. Gate tunable edge magnetoplasmon resonators

Author

Frigerio, E., Rebora, G., Ruelle, M., Souquet-Basiège, H., Jin, Y., Gennser, U., Cavanna, A., Plaçais, B., Baudin, E., Berroir, J. -M., Safi, I., Degiovanni, P., Fève, G., and Ménard, G.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Quantum Hall systems are platforms of choice when it comes to study topological properties of condensed matter systems and anyonic exchange statistics. In this work we have developed a tunable radiofrequency edge magnetoplasmonic resonator meant to serve as a versatile platform for future interferometric devices. The resonance frequency of the system is controlled by both the magnetic field and a set of electrostatic gates. The gates allow us to change both the size of the resonant cavity and the electronic density of the two-dimensional electron gas. We show that we can continuously control the frequency response of our resonator, making it possible to develop an edge magnetoplasmon interferometer. As we reach smaller sizes of our resonator, finite size effects caused by the measurement probes manifest. We present a theoretical description of the system taking into account the spatial extension of the probing gates. In the future, such device will be a valuable tool to investigate the properties of non-abelian anyons in the fractional quantum Hall regime.

Published

2024

3. Electroluminescence and Energy Transfer Mediated by Hyperbolic Polaritons

Author

Abou-Hamdan, L., Schmitt, A., Bretel, R., Rossetti, S., Tharrault, M., Mele, D., Pierret, A., Rosticher, M., Taniguchi, T., Watanabe, K., Maestre, C., Journet, C., Toury, B., Garnier, V., Steyer, P., Edgar, J. H., Janzen, E., Berroir, J-M., Fève, G., Ménard, G., Plaçais, B., Voisin, C., Hugonin, J-P., Bailly, E., Vest, B., Greffet, J-J., Bouchon, P., De Wilde, Y., and Baudin, E.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Under high electrical current, some materials can emit electromagnetic radiation beyond incandescence. This phenomenon, referred to as electroluminescence, leads to the efficient emission of visible photons and is the basis of domestic lighting devices (e.g., light-emitting diodes). In principle, electroluminescence can lead to mid-infrared (mid-IR) emission of confined light-matter excitations called phonon-polaritons, resulting from the coupling of photons with crystal lattice vibrations (optical phonons). In particular, phonon-polaritons arising in the van der Waals crystal hexagonal boron nitride (hBN) exhibit hyperbolic dispersion, which enhances light-matter coupling. For this reason, electroluminescence of hyperbolic phonon-polaritons (HPhPs) has been proposed as an explanation for the peculiar radiative energy transfer within hBN-encapsulated graphene transistors. However, since HPhPs are confined, they are inaccessible in the far-field, so that any hint of electroluminescence is only based on indirect electronic signatures and needs to be confirmed by direct observation. Here, we demonstrate far-field mid-IR ({\lambda} = 6.5 {\mu}m) electroluminescence of HPhPs excited by strongly biased high-mobility graphene within a van der Waals heterostructure, and we quantify the associated radiative energy transfer through the material. The presence of HPhPs is revealed via far-field mid-IR spectroscopy due to their elastic scattering at discontinuities in the heterostructure. The associated radiative flux is quantified by mid-IR pyrometry of the substrate receiving the energy. This radiative energy transfer is shown to be reduced in hBN with nanoscale inhomogeneities, demonstrating the central role of the electromagnetic environment in this process., Comment: 30 pages including Extended Data and Supplementary Material (Main text: 8 pages, 4 figures)

Published

2023

4. Electroluminescence of the graphene 2D semi-metal

Author

Schmitt, A., Abou-Hamdan, L., Tharrault, M., Rossetti, S., Mele, D., Bretel, R., Pierret, A., Rosticher, M., Morfin, P., Taniguchi, T., Watanabe, K., Berroir, J. M., Fève, G., Ménard, G., Plaçais, B., Voisin, C., Hugonin, J. P., Greffet, J. J., Bouchon, P., De Wilde, Y., and Baudin, E.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Electroluminescence, a non-thermal radiative process, is ubiquitous in semi-conductors and insulators but fundamentally precluded in metals. We show here that this restriction can be circumvented in high-quality graphene. By investigating the radiative emission of semi-metallic graphene field-effect transistors over a broad spectral range, spanning the near- and mid-infrared, we demonstrate direct far-field electroluminescence from hBN-encapsulated graphene in the mid-infrared under large bias in ambient conditions. Through a series of test experiments ruling out its incandescence origin, we determine that the electroluminescent signal results from the electrical pumping produced by interband tunneling. We show that the mid-infrared electroluminescence is spectrally shaped by a natural quarter-wave resonance of the heterostructure. This work invites a reassessment of the use of metals and semi-metals as non-equilibrium light emitters, and the exploration of their intriguing specificities in terms of carrier injection and relaxation, as well as emission tunability and switching speed., Comment: Main text (8 pages , 3 figures ) + Supplementary Information ( 19 pages , 19 figures)

Published

2023

5. Magneto-exciton limit of quantum Hall breakdown in graphene

Author

Schmitt, A., Rosticher, M., Taniguchi, T., Watanabe, K., Fève, G., Berroir, J-M., Ménard, G., Voisin, C., Goerbig, M. O., Plaçais, B., and Baudin, E.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

One of the intrinsic drift velocity limit of the quantum Hall effect is the collective magneto-exciton (ME) instability. It has been demonstrated in bilayer graphene (BLG) using noise measurements. We reproduce this experiment in monolayer graphene (MLG), and show that the same mechanism carries a direct relativistic signature on the breakdown velocity. Based on theoretical calculations of MLG- and BLG-ME spectra, we show that Doppler-induced instabilities manifest for a ME phase velocity determined by a universal value of the ME conductivity, set by the Hall conductance., Comment: 27 pages, 11 figures including supplementary information (14 pages and 3 figures for the main text alone)

Published

2023

6. High-field 1/f noise in hBN-encapsulated graphene transistors

Author

Schmitt, A., Mele, D., Rosticher, M., Taniguchi, T., Watanabe, K., Maestre, C., Journet, C., Garnier, V., Fève, G., Berroir, J. M., Voisin, C., Plaçais, B., and Baudin, E.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Low-frequency 1/f noise in electronics is a conductance fluctuation, that has been expressed in terms of a mobility "$\alpha$-noise" by Hooge and Kleinpenning. Understanding this noise in graphene is a key towards high-performance electronics. Early investigations in diffusive graphene have pointed out a deviation from the standard Hooge formula, with a modified expression where the free-carrier density is substituted by a constant density $n_\Delta\sim10^{12}\;\mathrm{cm^{-2}}$. We investigate hBN-encapsulated graphene transistors where high mobility gives rise to the non-linear velocity-saturation regime. In this regime, the $\alpha$-noise is accounted for by substituting conductance by differential conductance $G$, ressulting in a bell-shape dependence of flicker noise with bias voltage $V$. The same analysis holds at larger bias in the Zener regime, with two main differences: the first one is a strong enhancement of the Hooge parameter reflecting the hundred-times larger coupling of interband excitations to the hyperbolic phonon-polariton (HPhP) modes of the mid-infrared Reststrahlen (RS) bands of hBN. The second is an exponential suppression of this coupling at large fields, which we attribute to decoherence effects. We also show that the HPhP bands control the amplitude of flicker noise according to the graphene-hBN thermal coupling estimated with microwave noise thermometry. The phenomenology of $\alpha$-noise in graphene supports a quantum-coherent bremsstrahlung interpretation of flicker noise., Comment: v2, main + SI, added reference to open data on Zenodo repository

Published

2023

7. Observation of edge magnetoplasmon squeezing in a quantum Hall conductor

Author

Bartolomei, H., Bisognin, R., Kamata, H., Berroir, J. -M., Bocquillon, E., Ménard, G., Plaçais, B., Cavanna, A., Gennser, U., Jin, Y., Degiovanni, P., Mora, C., and Fève, G.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Squeezing of the quadratures of the electromagnetic field has been extensively studied in optics and microwaves. However, previous works focused on the generation of squeezed states in a low impedance ($Z_0 \approx 50 \Omega$) environment. We report here on the demonstration of the squeezing of bosonic edge magnetoplasmon modes in a quantum Hall conductor whose characteristic impedance is set by the quantum of resistance ($R_K \approx 25 k \Omega$), offering the possibility of an enhanced coupling to low-dimensional quantum conductors. By applying a combination of dc and ac drives to a quantum point contact, we demonstrate squeezing and observe a noise reduction 18\% below the vacuum fluctuations. This level of squeezing can be improved by using more complex conductors, such as ac driven quantum dots or mesoscopic capacitors., Comment: 6+2 pages, 3+1 figures

Published

2022

8. Comparing fractional quantum Hall Laughlin and Jain topological orders with the anyon collider

Author

Ruelle, M., Frigerio, E., Berroir, J. -M., Plaçais, B., Rech, J., Cavanna, A., Gennser, U., Jin, Y., and Fève, G.

Subjects

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

Abstract

Anyon collision experiments have recently demonstrated the ability to discriminate between fermionic and anyonic statistics. However, only one type of anyons associated with the simple Laughlin state at filling factor $\nu=1/3$ has been probed so far. It is now important to establish anyon collisions as quantitative probes of fractional statistics for more complex topological orders, with the ability to distinguish between different species of anyons with different statistics. In this work, we use the anyon collider to compare the Laughlin $\nu=1/3$ state, which is used as the reference state, with the more complex Jain state at $\nu=2/5$, where low energy excitations are carried by two co-propagating edge channels. We demonstrate that anyons generated on the outer channel of the $\nu=2/5$ state (with a fractional charge $e^*=e/3$) have a similar behavior compared to $\nu=1/3$, showing the robustness of anyon collision signals for anyons of the same type. In contrast, anyons emitted on the inner channel of $\nu=2/5$ (with a fractional charge $e^*=e/5$) exhibit a reduced degree of bunching compared to the $\nu=1/3$ case, demonstrating the ability of the anyon collider to discriminate not only between anyons and fermions, but also between different species of anyons associated with different topological orders of the bulk. Our experimental results for the inner channel of $\nu=2/5$ also point towards an influence of interchannel interactions in anyon collision experiments when several co-propagating edge channels are present. A quantitative understanding of these effects will be important for extensions of anyon collisions to non-abelian topological orders, where several charged and neutral modes propagate at the edge., Comment: 17 pages, 5 figures

Published

2022

9. Mesoscopic Klein-Schwinger effect in graphene

Author

Schmitt, A., Vallet, P., Mele, D., Rosticher, M., Taniguchi, T., Watanabe, K., Bocquillon, E., Fève, G., Berroir, J. M., Voisin, C., Cayssol, J., Goerbig, M. O., Troost, J., Baudin, E., and Plaçais, B.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, High Energy Physics - Theory

Abstract

Strong electric field annihilation by particle-antiparticle pair creation, also known as the Schwinger effect, is a non-perturbative prediction of quantum electrodynamics. Its experimental demonstration remains elusive, as threshold electric fields are extremely strong and beyond current reach. Here, we propose a mesoscopic variant of the Schwinger effect in graphene, which hosts Dirac fermions with an approximate electron-hole symmetry. Using transport measurements, we report on universal 1d-Schwinger conductance at the pinchoff of ballistic graphene transistors. Strong pinchoff electric fields are concentrated within approximately 1 $\mu$m of the transistor's drain, and induce Schwinger electron-hole pair creation at saturation. This effect precedes a collective instability toward an ohmic Zener regime, which is rejected at twice the pinchoff voltage in long devices. These observations advance our understanding of current saturation limits in ballistic graphene and provide a direction for further quantum electrodynamic experiments in the laboratory., Comment: 39 pages, 13 figures, final version with extended discussion of the pinchoff effect in supplementary informations, abstract updated

Published

2022

10. Anyon collisions and fractional statistics

Author

Fève, G., primary

Published

2024

11. Dielectric permittivity, conductivity and breakdown field of hexagonal boron nitride

Author

Pierret, A., Mele, D., Graef, H., Palomo, J., Taniguchi, T., Watanabe, K., Li, Y., Toury, B., Journet, C., Steyer, P., Garnier, V., Loiseau, A., Berroir, J-M., Bocquillon, E., Fève, G., Voisin, C., Baudin, E., Rosticher, M., and Plaçais, B.

Subjects

Condensed Matter - Materials Science

Abstract

In view of the extensive use of hexagonal boron nitride (hBN) in 2D material electronics, it becomes important to refine its dielectric characterization in terms of low-field permittivity and high-field strength and conductivity up to the breakdown voltage. The present study aims at filling this gap using DC and RF transport in two Au-hBN-Au capacitor series of variable thickness in the 10--100 nm range, made of large high-pressure, high-temperature (HPHT) crystals and a polymer derivative ceramics (PDC) crystals. We deduce an out-of-plane low field dielectric constant $\epsilon_\parallel=3.4\pm0.2$ consistent with the theoretical prediction of Ohba et al., that narrows down the generally accepted window $\epsilon_\parallel=3$--$4$. The DC-current leakage at high-field is found to obey the Frenkel-Pool law for thermally-activated trap-assisted electron transport with a dynamic dielectric constant $\epsilon_\parallel\simeq3.1$ and a trap energy $\Phi_B\simeq1.3\;\mathrm{eV}$, that is comparable with standard technologically relevant dielectrics., Comment: 10 pages, 2 figures, AM version in Materials Research Express

Published

2022

12. Mesoscopic Klein-Schwinger effect in graphene

Author

Schmitt, A., Vallet, P., Mele, D., Rosticher, M., Taniguchi, T., Watanabe, K., Bocquillon, E., Fève, G., Berroir, J. M., Voisin, C., Cayssol, J., Goerbig, M. O., Troost, J., Baudin, E., and Plaçais, B.

Published

2023

13. Fractional statistics in anyon collisions

Author

Bartolomei, H., Kumar, M., Bisognin, R., Marguerite, A., Berroir, J. -M., Bocquillon, E., Plaçais, B., Cavanna, A., Dong, Q., Gennser, U., Jin, Y., and Fève, G.

Subjects

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

Abstract

Two-dimensional systems can host exotic particles called anyons whose quantum statistics are neither bosonic nor fermionic. For example, the elementary excitations of the fractional quantum Hall effect at filling factor $\nu=1/m$ (where m is an odd integer) have been predicted to obey abelian fractional statistics, with a phase $\varphi$ associated with the exchange of two particles equal to $\pi/m$. However, despite numerous experimental attempts, clear signatures of fractional statistics remain elusive. Here we experimentally demonstrate abelian fractional statistics at filling factor $\nu=1/3$ by measuring the current correlations resulting from the collision between anyons at a beam-splitter. By analyzing their dependence on the anyon current impinging on the splitter and comparing with recent theoretical models, we extract $\varphi=\pi/3$, in agreement with predictions., Comment: 5 pages, supplementary material can be downloaded at https://science.sciencemag.org/content/368/6487/173/suppl/DC1

Published

2020

14. Quantum tomography of electrical currents

Author

Bisognin, R., Marguerite, A., Roussel, B., Kumar, M., Cabart, C., Chapdelaine, C., Mohammad-Djafari, A., Berroir, J. -M., Bocquillon, E., Plaçais, B., Cavanna, A., Gennser, U., Jin, Y., Degiovanni, P., and Fève, G.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

In quantum nanoelectronics, time-dependent electrical currents are built from few elementary excitations emitted with well-defined wavefunctions. However, despite the realization of sources generating quantized numbers of excitations, and despite the development of the theoretical framework of time-dependent quantum electronics, extracting electron and hole wavefunctions from electrical currents has so far remained out of reach, both at the theoretical and experimental levels. In this work, we demonstrate a quantum tomography protocol which extracts the generated electron and hole wavefunctions and their emission probabilities from any electrical current. It combines two-particle interferometry with signal processing. Using our technique, we extract the wavefunctions generated by trains of Lorentzian pulses carrying one or two electrons. By demonstrating the synthesis and complete characterization of electronic wavefunctions in conductors, this work offers perspectives for quantum information processing with electrical currents and for investigating basic quantum physics in many-body systems., Comment: Preprint version, supplementary material is available at https://static-content.springer.com/esm/art%3A10.1038%2Fs41467-019-11369-5/MediaObjects/41467_2019_11369_MOESM1_ESM.pdf

Published

2020

15. Microwave photons emitted by fractionally charged quasiparticles

Author

Bisognin, R., Bartolomei, H., Kumar, M., Safi, I., Berroir, J. -M., Bocquillon, E., Plaçais, B., Cavanna, A., Gennser, U., Jin, Y., and Fève, G.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Strongly correlated low-dimensional systems can host exotic elementary excitations carrying a fractional charge $q$ and potentially obeying anyonic statistics. In the fractional quantum Hall effect, their fractional charge has been successfully determined owing to low frequency shot noise measurements. However, a universal method for sensing them unambiguously and unraveling their intricate dynamics was still lacking. Here, we demonstrate that this can be achieved by measuring the microwave photons emitted by such excitations when they are transferred through a potential barrier biased with a dc voltage $V_{\text{dc}}$. We observe that only photons at frequencies $f$ below $qV_{\text{dc}}/h$ are emitted. This threshold provides a direct and unambiguous determination of the charge $q$, and a signature of exclusion statistics. Derived initially within the Luttinger model, this feature is also predicted by universal non-equilibrium fluctuation relations which agree fully with our measurements. Our work paves the way for further exploration of anyonic statistics using microwave measurements., Comment: 16 pages, 4 figures

Published

2019

16. A corner reflector of graphene Dirac fermions as a phonon-scattering sensor

Author

Graef, H., Wilmart, Q., Rosticher, M., Mele, D., Banszerus, L., Stampfer, C., Taniguchi, T., Watanabe, K., Berroir, J-M., Bocquillon, E., Fève, G., Teo, E. H. T., and Plaçais, B.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Dirac fermion optics exploits the refraction of chiral fermions across optics-inspired Klein-tunneling barriers defined by high-transparency p-n junctions. We consider the corner reflector (CR) geometry introduced in optics or radars. We fabricate Dirac fermion CRs using bottom-gate-defined barriers in hBN-encapsulated graphene. By suppressing transmission upon multiple internal reflections, CRs are sensitive to minute phonon scattering rates. We report on doping-independent CR transmission in quantitative agreement with a simple scattering model including thermal phonon scattering. As a new signature of CRs, we observe Fabry-P\'erot oscillations at low temperature, consistent with single-path reflections. Finally, we demonstrate high-frequency operation which promotes CRs as fast phonon detectors. Our work establishes the relevance of Dirac fermion optics in graphene and opens a route for its implementation in topological Dirac matter., Comment: 11 pages, 4 figures

Published

2019

17. Ultra-long wavelength Dirac plasmons in graphene capacitors

Author

Graef, H., Mele, D., Rosticher, M., Stampfer, C., Taniguchi, T., Watanabe, K., Bocquillon, E., Fève, G., Berroir, J-M., Teo, E. H. T., and Plaçais, B.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Graphene is a valuable 2D platform for plasmonics as illustrated in recent THz and mid-infrared optics experiments. These high-energy plasmons however, couple to the dielectric surface modes giving rise to hybrid plasmon-polariton excitations. Ultra-long-wavelengthes address the low energy end of the plasmon spectrum, in the GHz-THz electronic domain, where intrinsic graphene Dirac plasmons are essentially decoupled from their environment. However experiments are elusive due to the damping by ohmic losses at low frequencies. We demonstrate here a plasma resonance capacitor (PRC) using hexagonal boron-nitride (hBN) encapsulated graphene at cryogenic temperatures in the near ballistic regime. We report on a $100\;\mathrm{\mu m}$ quarter-wave plasmon mode, at $40\;\mathrm{GHz}$, with a quality factor $Q\simeq2$. The accuracy of the resonant technique yields a precise determination of the electronic compressibility and kinetic inductance, allowing to assess residual deviations from intrinsic Dirac plasmonics. Our capacitor GHz experiment constitutes a first step toward the demonstration of plasma resonance transistors for microwave detection in the sub-THz domain for wireless communications and sensing. It also paves the way to the realization of doping modulated superlattices where plasmon propagation is controlled by Klein tunneling., Comment: 10 pages, 3 figures

Published

2018

18. Landau velocity for collective quantum Hall breakdown in bilayer graphene

Author

Yang, W., Graef, H., Lu, X., Zhang, G., Taniguchi, T., Watanabe, K., Bachtold, A., Teo, E. H. T., Baudin, E., Bocquillon, E., Fève, G., Berroir, J-M., Carpentier, D., Goerbig, M. O., and Plaçais, B.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Breakdown of the quantum Hall effect (QHE) is commonly associated with an electric field approaching the inter Landau-level (LL) Zener field, ratio of the Landau gap and cyclotron radius. Eluded in semiconducting heterostructures, in spite of extensive investigation, the intrinsic Zener limit is reported here using high-mobility bilayer graphene and high-frequency current noise. We show that collective excitations arising from electron-electron interactions are essential. Beyond a noiseless ballistic QHE regime a large superpoissonian shot noise signals the breakdown via inter-LL scattering. The breakdown is ultimately limited by collective excitations in a regime where phonon and impurity scattering are quenched. The breakdown mechanism can be described by a Landau critical velocity as it bears strong similarities with the roton mechanism of superfluids., Comment: 13 pages, 3 figures

Published

2018

19. Onset of optical-phonon cooling in multilayer graphene revealed by RF noise and black-body radiation thermometries

Author

Brunel, D., Berthou, S., Parret, R., Vialla, F., Morfin, P., Wilmart, Q., Fève, G., Berroir, J. -M., Roussignol, P., Voisin, C., and Plaçais, B.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We report on electron cooling power measurements in few-layer graphene excited by Joule heating by means of a new setup combining electrical and optical probes of the electron and phonon baths temperatures. At low bias, noise thermometry allows us to retrieve the well known acoustic phonon cooling regimes below and above the Bloch Gr\"uneisen temperature, with additional control over the phonon bath temperature. At high electrical bias, we show the relevance of direct optical investigation of the electronic temperature by means of black-body radiation measurements that provide higher accuracy than noise thermometry. In this regime, the onset of new efficient relaxation pathways involving optical modes is observed

Published

2018

20. Contact gating at GHz frequency in graphene

Author

Wilmart, Q., Inhofer, A., Boukhicha, M., Yang, W., Rosticher, M., Morfin, P., Garroum, N., Fève, G., Berroir, J. -M., and Plaçais, B.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The paradigm of graphene transistors is based on the gate modulation of the channel carrier density by means of a local channel gate. This standard architecture is subject to the scaling limit of the channel length and further restrictions due to access and contact resistances impeding the device performance. We propose a novel design, overcoming these issues by implementing additional local gates underneath the contact region which allow a full control of the Klein barrier taking place at the contact edge. In particular, our work demonstrates the GHz operation of transistors driven by independent contact gates. We benchmark the standard channel and novel contact gating and report for the later dynamical transconductance levels at the state of the art. Our finding may find applications in electronics and optoelectronics whenever there is need to control independently the Fermi level and the electrostatic potential of electronic sources or to get rid of cumbersome local channel gates.

Published

2018

21. Taming electronic decoherence in 1D chiral ballistic quantum conductors

Author

Cabart, C., Roussel, B., Fève, G., and Degiovanni, P.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Although interesting per se, decoherence and relaxation of single-electron excitations induced by strong effective screened Coulomb interactions in Quantum Hall edge channels are an important challenge for the applications of electron quantum optics in quantum information and quantum sensing. In this paper, we study intrinsic single-electron decoherence within an ideal single-electron channel with long-range effective Coulomb interactions to determine the influence of the material and sample properties. We find that weak-coupling materials characterized by a high velocity of hot-electron excitations may offer interesting perspectives for limiting intrinsic decoherence due to electron/electron interactions. We discuss quantitively how extrinsic decoherence due to the coupling with the channel's electromagnetic environment can be efficiently inhibited in specially designed samples at $\nu=2$ with one closed edge channel and we propose a realistic geometry for testing decoherence control in an Hong Ou Mandel experiment., Comment: 28 pages, 28 figures

Published

2018

22. Extracting single electron wavefunctions from a quantum electrical current

Author

Marguerite, A., Roussel, B., Bisognin, R., Cabart, C., Kumar, M., Berroir, J. -M., Bocquillon, E., Plaçais, B., Cavanna, A., Gennser, U., Jin, Y., Degiovanni, P., and Fève, G.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Quantum nanoelectronics has entered an era where quantum electrical currents are built from single to few on-demand elementary excitations. To date however, very limited tools have been implemented to characterize them. In this work, we present a quantum current analyzer able to extract single particle excitations present within a periodic quantum electrical current without any a priori hypothesis. Our analyzer combines two-particle interferometry and signal processing to extract the relevant electron and hole wavefunctions localized around each emission period and their quantum coherence from one emission period to the other. This quantum current analyzer opens new possibilities for the characterization and control of quantum electrical currents in nanoscale conductors and for investigations of entanglement in quantum electronics down to the single electron level., Comment: submitted, 6 pages plus 3 pages supplementary

Published

2017

23. RF-quantum capacitance of the topological insulator Bi2Se3 in the bulk depleted regime for field-effect transistors

Author

Inhofer, A., Duffy, J., Boukhicha, M., Bocquillon, E., Palomo, J., Watanabe, K., Taniguchi, T., Estève, I., Berroir, J. M., Fève, G., Plaçais, B., and Assaf, B. A.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

A Metal-dielectric-topological insulator capacitor device based on hBN-encapsulated CVD grown Bi2Se3 is realized and investigated in the radio frequency regime. The RF quantum capacitance and device resistance are extracted for frequencies as a high as 10 GHz, and studied as a function of the applied gate voltage. The combination of the superior quality hBN dielectric gate with the optimized transport characteristics of CVD grown Bi2Se3 (n~10^18cm-3 in 8 nm) allow us to attain a bulk depleted regime by dielectric gating. A quantum capacitance minimum is observed revealing a purely Dirac regime, where the Dirac surface state in proximity to the gate reaches charge neutrality, but the bottom surface Dirac cone remains charged, and couples capacitively to the top surface via the insulating bulk. Our work paves the way towards implementation of topological materials in RF devices., Comment: accepted Phys. Rev. Applied

Published

2017

24. Observation of Volkov-Pankratov states in topological HgTe heterojunctions using high-frequency compressibility

Author

Inhofer, A., Tchoumakov, S., Assaf, B. A., Fève, G., Berroir, J. M., Jouffrey, V., Carpentier, D., Goerbig, M., Plaçais, B., Bendias, K., Mahler, D. M., Bocquillon, E., Schlereth, R., Brüne, C., Buhmann, H., and Molenkamp, L. W.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

It is well established that topological insulators sustain Dirac fermion surface states as a consequence of band inversion in the bulk. These states have a helical spin polarization and a linear dispersion with large Fermi velocity. In this article we report on a set of experimental observations indicating the existence of massive surface states. These states are confined at the interface and dominate equilibrium and transport properties at high energy and/or high electric field. By monitoring the AC admittance of HgTe topological insulator field-effect capacitors, we access the compressibility and conductivity of surface states in a broad range of energy and electric fields. The Dirac surface states are characterized by a compressibility minimum, a linear energy dependence and a high mobility persisting up to energies much larger than the transport bandgap of the bulk. New features are revealed at high energies with signatures such as conductance peaks, compressibility bumps, a strong charge metastability and a Hall resistance anomaly. These features point to the existence of excited massive surface states, responsible for a strong intersubband scattering with the Dirac states and the nucleation of metastable bulk carriers. The spectrum of excited states agrees with predictions of a phenomenological model of the topological-trivial semiconductor interface. The model accounts for the finite interface depth and the effect of electric fields. The existence of excited topological states is essential for the understanding of topological phases and opens a route for engineering and exploiting topological resources in quantum technology., Comment: 29 pages, 8 figures

Published

2017

25. A graphene Zener-Klein transistor cooled by a hyperbolic substrate

Author

Yang, W., Berthou, S., Lu, X., Wilmart, Q., Denis, A., Rosticher, M., Taniguchi, T., Watanabe, K., Feve, G., Berroir, J. M., Zhang, G., Voisin, C., Baudin, E., and Plaçais, B.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Engineering of cooling mechanisms is a bottleneck in nanoelectronics. Whereas thermal exchanges in diffusive graphene are mostly driven by defect assisted acoustic phonon scattering, the case of high-mobility graphene on hexagonal Boron Nitride (hBN) is radically different with a prominent contribution of remote phonons from the substrate. A bi-layer graphene on hBN transistor with local gate is driven in a regime where almost perfect current saturation is achieved by compensation of the decrease of the carrier density and Zener-Klein tunneling (ZKT) at high bias. Using noise thermometry, we show that this Zener-Klein tunneling triggers a new cooling pathway due to the emission of hyperbolic phonon polaritons (HPP) in hBN by out-of-equilibrium electron-hole pairs beyond the super-Planckian regime. The combination of ZKT-transport and HPP-cooling promotes graphene on BN transistors as a valuable nanotechnology for power devices and RF electronics., Comment: 15 pages, 4 figures

Published

2017

26. Anyonic and Fermionic Statistics in a Mesoscopic Collider

Author

Bartolomei, H., primary, Kumar, M., additional, Ruelle, M., additional, and Fève, G., additional

Published

2022

27. Electron quantum optics as quantum signal processing

Author

Roussel, B., Cabart, C., Fève, G., Thibierge, E., and Degiovanni, P.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

The recent developments of electron quantum optics in quantum Hall edge channels have given us new ways to probe the behavior of electrons in quantum conductors. It has brought new quantities called electronic coherences under the spotlight. In this paper, we explore the relations between electron quantum optics and signal processing through a global review of the various methods for accessing single- and two-electron coherences in electron quantum optics. We interpret electron quantum optics interference experiments as analog signal processing converting quantum signals into experimentally observable quantities such as current averages and correlations. This point of view also gives us a procedure to obtain quantum information quantities from electron quantum optics coherences. We illustrate these ideas by discussing two mode entanglement in electron quantum optics. We also sketch how signal processing ideas may open new perspectives for representing electronic coherences in quantum conductors and understand the properties of the underlying many-body electronic state., Comment: 19 pages, 9 figures, to appear in Physical Status Solidi B focus issue on 'Single-electron control in solid-state devices'. Version 2 & 3: expanded section 2 with extra-references reviewing electron quantum optics in other systems and updated bibliography+ corrected misprints + corrected Figs. 8 & 9 and associated comments due to a small error in numerics: no change to conclusions

Published

2016

28. Hong-Ou-Mandel experiment for temporal investigation of single electron fractionalization

Author

Freulon, V., Marguerite, A., Berroir, J. -M, Plaçais, B., Cavanna, A., Jin, Y., and Fève, G.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Coulomb interaction has a striking effect on electronic propagation in one dimensional conductors. The interaction of an elementary excitation with neighboring conductors favors the emergence of collective modes which eventually leads to the destruction of the Landau quasiparticle. In this process, an injected electron tends to fractionalize into separated pulses carrying a fraction of the electron charge. Here we use two-particle interferences in the electronic analog of the Hong-Ou-Mandel experiment in a quantum Hall conductor at filling factor 2 to probe the fate of a single electron emitted in the outer edge channel and interacting with the inner one. By studying both channels, we analyze the propagation of the single electron and the generation of interaction induced collective excitations in the inner channel. These complementary information reveal the fractionalization process in time domain and establish its relevance for the destruction of the quasiparticle which degrades into the collective modes.

Published

2016

29. Decoherence and relaxation of a single electron in a one dimensional conductor

Author

Marguerite, A., Cabart, C., Wahl, C., Roussel, B., Freulon, V., Ferraro, D., Grenier, Ch., Berroir, J. -M., Plaçais, B., Jonckheere, T., Rech, J., Martin, T., Degiovanni, P., Cavanna, A., Jin, Y., and Fève, G.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We study the decoherence and relaxation of a single elementary electronic excitation propagating in a one-dimensional chiral conductor. Using two-particle interferences in the electronic analog of the Hong-Ou-Mandel experiment, we analyze quantitatively the decoherence scenario of a single electron propagating along a quantum Hall edge channel at filling factor 2. The decoherence results from the emergence of collective neutral excitations induced by Coulomb interaction and leading, in one dimension, to the destruction of the elementary quasiparticle. This study establishes the relevance of electron quantum optics setups to provide stringent tests of strong interaction effects in one-dimensional conductors described by Luttinger liquids paradigm., Comment: 24 pages, 6 figures To be published in Physical Review B

Published

2016

30. Two-electron coherence and its measurement in electron quantum optics

Author

Thibierge, E., Ferraro, D., Roussel, B., Cabart, C., Marguerite, A., Fève, G., and Degiovanni, P.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

Engineering and studying few-electron states in ballistic conductors is a key step towards understanding entanglement in quantum electronic systems. In this Letter, we introduce the intrinsic two-electron coherence of an electronic source in quantum Hall edge channels and relate it to two-electron wavefunctions and to current noise in an Hanbury Brown--Twiss interferometer. Inspired by the analogy with photon quantum optics, we propose to measure the intrinsic two-electron coherence of a source using low-frequency current correlation measurements at the output of a Franson interferometer. To illustrate this protocol, we discuss how it can distinguish between a time-bin entangled pure state and a statistical mixture of time shifted electron pairs., Comment: 6 pages, 6 figures, version 2 with improved introduction and bibliography

Published

2015

31. Real time decoherence of Landau and Levitov quasi-particles in quantum Hall edge channels

Author

Ferraro, D., Roussel, B., Cabart, C., Thibierge, E., Fève, G., Grenier, C., and Degiovanni, P.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

Quantum Hall edge channels at integer filling factor provide a unique test-bench to understand decoherence and relaxation of single electronic excitations in a ballistic quantum conductor. In this Letter, we obtain a full visualization of the decoherence scenario of energy (Landau) and time (Levitov) resolved single electron excitations at filling factor $\nu=2$. We show that the Landau excitation exhibits a fast relaxation followed by spin-charge separation whereas the Levitov excitation only experiences spin-charge separation. We finally suggest to use Hong-Ou-Mandel type experiments to probe specific signatures of these different scenarios., Comment: 14 pages, 8 figures

Published

2014

32. Electron quantum optics in ballistic chiral conductors

Author

Bocquillon, E., Freulon, V., Parmentier, F. D., Berroir, J. -M, Plaçais, B., Wahl, C., Rech, J., Jonckheere, T., Martin, T., Grenier, C., Ferraro, D., Degiovanni, P., and Fève, G.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The edge channels of the quantum Hall effect provide one dimensional chiral and ballistic wires along which electrons can be guided in optics like setup. Electronic propagation can then be analyzed using concepts and tools derived from optics. After a brief review of electron optics experiments performed using stationary current sources which continuously emit electrons in the conductor, this paper focuses on triggered sources, which can generate on-demand a single particle state. It first outlines the electron optics formalism and its analogies and differences with photon optics and then turns to the presentation of single electron emitters and their characterization through the measurements of the average electrical current and its correlations. This is followed by a discussion of electron quantum optics experiments in the Hanbury-Brown and Twiss geometry where two-particle interferences occur. Finally, Coulomb interactions effects and their influence on single electron states are considered.

Published

2014

33. Separation of neutral and charge modes in one dimensional chiral edge channels

Author

Bocquillon, E., Freulon, V., Berroir, J. -M., Degiovanni, P., Plaçais, B., Cavanna, A., Jin, Y., and Fève, G.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Coulomb interactions have a major role in one-dimensional electronic transport. They modify the nature of the elementary excitations from Landau quasiparticles in higher dimensions to collective excitations in one dimension. Here we report the direct observation of the collective neutral and charge modes of the two chiral co-propagating edge channels of opposite spins of the quantum Hall effect at filling factor 2. Generating a charge density wave at frequency f in the outer channel, we measure the current induced by inter-channel Coulomb interaction in the inner channel after a 3-mm propagation length. Varying the driving frequency from 0.7 to 11 GHz, we observe damped oscillations in the induced current that result from the phase shift between the fast charge and slow neutral eigenmodes. We measure the dispersion relation and dissipation of the neutral mode from which we deduce quantitative information on the interaction range and parameters., Comment: 23 pages, 6 figures

Published

2013

34. Wigner function approach to single electron coherence in quantum Hall edge channels

Author

Ferraro, D., Feller, A., Ghibaudo, A., Thibierge, E., Bocquillon, E., Fève, G., Grenier, C., and Degiovanni, P.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Recent electron quantum optics experiments performed with on-demand single electron sources call for a mixed time/frequency approach to electronic quantum coherence. Here, we present a Wigner function representation of first order electronic coherence and show that is provides a natural visualization of the excitations emitted by recently demonstrated single electron sources. It also gives a unified perspective on single particle and two particle interferometry experiments. In particular, we introduce a non-classicality criterion for single electron coherence and discuss it in the context of Mach-Zenhder interferometry. Finally, the electronic Hanbury Brown and Twiss and the Hong Ou Mandel experiments are interpreted in terms of overlaps of Wigner function thus connecting them to signal processing., Comment: 19 pages and 11 figures

Published

2013

35. Coherence and Indistinguishability of Single Electrons Emitted by Independent Sources

Author

Bocquillon, E., Freulon, V., Berroir, J. -M, Degiovanni, P., Plaçais, B., Cavanna, A., Jin, Y., and Fève, G.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The on-demand emission of coherent and indistinguishable electrons by independent synchronized sources is a challenging task of quantum electronics, in particular regarding its application for quantum information processing. Using two independent on-demand electron sources, we trigger the emission of two single-electron wavepackets at different inputs of an electronic beamsplitter. Whereas classical particles would be randomly partitioned by the splitter, we observe two-particle interferences resulting from quantum exchange. Both electrons, emitted in indistinguishable wavepackets with synchronized arrival time on the splitter, exit in different outputs as recorded by the low frequency current noise. The demonstration of two-electron interference provides the possibility to manipulate coherent and indistinguishable single-electron wavepackets in quantum conductors., Comment: Science Express of January 24 2013

Published

2013

36. Supercollision cooling in undoped graphene

Author

Betz, A. C., Jhang, S. H., Pallecchi, E., Feirrera, R., Fève, G., Berroir, J. -M., and Plaçais, B.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Carrier mobility in solids is generally limited by electron-impurity or electron-phonon scattering depending on the most frequently occurring event. Three body collisions between carriers and both phonons and impurities are rare; they are denoted supercollisions (SCs). Elusive in electronic transport they should emerge in relaxation processes as they allow for large energy transfers. As pointed out in Ref. \onlinecite{Song2012PRL}, this is the case in undoped graphene where the small Fermi surface drastically restricts the allowed phonon energy in ordinary collisions. Using electrical heating and sensitive noise thermometry we report on SC-cooling in diffusive monolayer graphene. At low carrier density and high phonon temperature the Joule power $P$ obeys a $P\propto T_e^3$ law as a function of electronic temperature $T_e$. It overrules the linear law expected for ordinary collisions which has recently been observed in resistivity measurements. The cubic law is characteristic of SCs and departs from the $T_e^4$ dependence recently reported for metallic graphene below the Bloch-Gr\"{u}neisen temperature. These supercollisions are important for applications of graphene in bolometry and photo-detection.

Published

2012

37. Hot electron cooling by acoustic phonons in graphene

Author

Betz, A. C., Vialla, F., Brunel, D., Voisin, C., Picher, M., Cavanna, A., Madouri, A., Fève, G., Berroir, J. -M., Plaçais, B., and Pallecchi, E.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We have investigated the energy loss of hot electrons in metallic graphene by means of GHz noise thermometry at liquid helium temperature. We observe the electronic temperature T / V at low bias in agreement with the heat diffusion to the leads described by the Wiedemann-Franz law. We report on $T\propto\sqrt{V}$ behavior at high bias, which corresponds to a T4 dependence of the cooling power. This is the signature of a 2D acoustic phonon cooling mechanism. From a heat equation analysis of the two regimes we extract accurate values of the electron-acoustic phonon coupling constant $\Sigma$ in monolayer graphene. Our measurements point to an important effect of lattice disorder in the reduction of $\Sigma$, not yet considered by theory. Moreover, our study provides a strong and firm support to the rising field of graphene bolometric detectors., Comment: 5 figures

Published

2012

38. Electron quantum optics : partitioning electrons one by one

Author

Bocquillon, E., Parmentier, F. D., Grenier, C., Berroir, J. -M., Degiovanni, P., Glattli, D. C., Plaçais, B., Cavanna, A., Jin, Y., and Fève, G.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We have realized a quantum optics like Hanbury Brown and Twiss (HBT) experiment by partitioning, on an electronic beam-splitter, single elementary electronic excitations produced one by one by an on-demand emitter. We show that the measurement of the output currents correlations in the HBT geometry provides a direct counting, at the single charge level, of the elementary excitations (electron/hole pairs) generated by the emitter at each cycle. We observe the antibunching of low energy excitations emitted by the source with thermal excitations of the Fermi sea already present in the input leads of the splitter, which suppresses their contribution to the partition noise. This effect is used to probe the energy distribution of the emitted wave-packets., Comment: 5 pages, 4 figures

Published

2012

39. Current noise spectrum of a single particle emitter: theory and experiment

Author

Parmentier, F. D., Bocquillon, E., Berroir, J. -M., Glattli, D. C., Plaçais, B., Fève, G., Albert, M., Flindt, C., and Büttiker, M.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The controlled and accurate emission of coherent electronic wave packets is of prime importance for future applications of nano-scale electronics. Here we present a theoretical and experimental analysis of the finite-frequency noise spectrum of a periodically driven single electron emitter. The electron source consists of a mesoscopic capacitor that emits single electrons and holes into a chiral edge state of a quantum Hall sample. We compare experimental results with two complementary theoretical descriptions: On one hand, the Floquet scattering theory which leads to accurate numerical results for the noise spectrum under all relevant operating conditions. On the other hand, a semi-classical model which enables us to develop an analytic description of the main sources of noise when the emitter is operated under optimal conditions. We find excellent agreement between experiment and theory. Importantly, the noise spectrum provides us with an accurate description and characterization of the mesoscopic capacitor when operated as a periodic single electron emitter., Comment: 17 pages, 15 figures

Published

2011

40. Coupling a quantum dot, fermionic leads and a microwave cavity on-chip

Author

Delbecq, M. R., Schmitt, V., Parmentier, F. D., Roch, N., Viennot, J. J., Fève, G., Huard, B., Mora, C., Cottet, A., and Kontos, T.

Subjects

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

Abstract

We demonstrate a hybrid architecture consisting of a quantum dot circuit coupled to a single mode of the electromagnetic field. We use single wall carbon nanotube based circuits inserted in superconducting microwave cavities. By probing the nanotube-dot using a dispersive read-out in the Coulomb blockade and the Kondo regime, we determine an electron-photon coupling strength which should enable circuit QED experiments with more complex quantum dot circuits., Comment: 4 pages, 4 figures

Published

2011

41. Noisy Kondo impurities

Author

Delattre, T., Feuillet-Palma, C., Herrmann, L. G., Morfin, P., Berroir, J. -M., Fève, G., Plaçais, B., Glattli, D. C., Choi, M. -S., Mora, C., and Kontos, T.

Subjects

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

Abstract

The anti-ferromagnetic coupling of a magnetic impurity carrying a spin with the conduction electrons spins of a host metal is the basic mechanism responsible for the increase of the resistance of an alloy such as Cu${}_{0.998}$Fe${}_{0.002}$ at low temperature, as originally suggested by Kondo . This coupling has emerged as a very generic property of localized electronic states coupled to a continuum . The possibility to design artificial controllable magnetic impurities in nanoscopic conductors has opened a path to study this many body phenomenon in unusual situations as compared to the initial one and, in particular, in out of equilibrium situations. So far, measurements have focused on the average current. Here, we report on \textit{current fluctuations} (noise) measurements in artificial Kondo impurities made in carbon nanotube devices. We find a striking enhancement of the current noise within the Kondo resonance, in contradiction with simple non-interacting theories. Our findings provide a test bench for one of the most important many-body theories of condensed matter in out of equilibrium situations and shed light on the noise properties of highly conductive molecular devices., Comment: minor differences with published version

Published

2010

42. Transport scattering time probed through rf admittance of a graphene capacitor

Author

Pallecchi, E., Betz, A. C., Chaste, J., Fève, G., Huard, B., Kontos, T., Berroir, J. -M., and Plaçais, B.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We have investigated electron dynamics in top gated graphene by measuring the gate admittance of a diffusive graphene capacitor in a broad frequency range as a function of carrier density. The density of states, conductivity and diffusion constant are deduced from the low frequency gate capacitance, its charging time and their ratio. The admittance evolves from an RC-like to a skin-effect response at GHz frequency with a crossover given by the Thouless energy. The scattering time is found to be independent of energy in the 0 - 200 meV investigated range at room temperature. This is consistent with a random mass model for Dirac Fermions., Comment: 6 pages, 6 figures

Published

2010

43. Current correlations of an on-demand electron source as an evidence of single particle emission

Author

Mahé, A., Parmentier, F. D., Bocquillon, E., Berroir, J. -M., Glattli, D. C., Kontos, T., Plaçais, B., Fève, G., Cavanna, A., and Jin, Y.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

In analogy with quantum optics, short time correlations of the current fluctuations are used to characterize an on-demand electron source consisting of a quantum dot connected to a conductor via a tunable tunnel barrier. We observe a new fundamental noise for electrons associated with the quantum fluctuations of the electron emission time, which we call quantum jitter. In optimum operating conditions of the source, the noise reduces to the quantum jitter limit, which demonstrates single particle emission. Combined with the coherent manipulations of single electrons in a quantum conductor, this electron quantum optics experiment opens the way to explore new problems including quantum statistics and interactions at the single electron level.

Published

2010

44. Conserved spin and orbital phase along carbon nanotubes connected with multiple ferromagnetic contacts

Author

Feuillet-Palma, C., Delattre, T., Morfin, P., Berroir, J. -M., Fève, G., Glattli, D. C., Placais, B., Cottet, A., and Kontos, T.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We report on spin dependent transport measurements in carbon nanotubes based multi-terminal circuits. We observe a gate-controlled spin signal in non-local voltages and an anomalous conductance spin signal, which reveal that both the spin and the orbital phase can be conserved along carbon nanotubes with multiple ferromagnetic contacts. This paves the way for spintronics devices exploiting both these quantum mechanical degrees of freedom on the same footing., Comment: 8 pages - minor differences with published version

Published

2010

45. Thermal shot noise in top-gated single carbon nanotube field effect transistors

Author

Chaste, J., Pallecchi, E., Morfin, P., Feve, G., Kontos, T., Berroir, J. -M., Hakonen, P., and Placais, B.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The high-frequency transconductance and current noise of top-gated single carbon nanotube transistors have been measured and used to investigate hot electron effects in one-dimensional transistors. Results are in good agreement with a theory of 1-dimensional nano-transistor. In particular the prediction of a large transconductance correction to the Johnson-Nyquist thermal noise formula is confirmed experimentally. Experiment shows that nanotube transistors can be used as fast charge detectors for quantum coherent electronics with a resolution of $13\mathrm{\mu e/\sqrt{Hz}}$ in the 0.2-$0.8 \mathrm{GHz}$ band., Comment: 3 pages, 4 figures

Published

2010

46. Quantum detection of electronic flying qubits

Author

Fève, G., Degiovanni, P., and Jolicoeur, Th.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We consider a model of a detector of ballistic electrons at the edge of a two-dimensional electron gas in the integer quantum Hall regime. The electron is detected by capacitive coupling to a gate which is also coupled to a passive RC circuit. Using a quantum description of this circuit, we determine the signal over noise ratio of the detector in term of the detector characteristics. The back-action of the detector on the incident wavepacket is then computed using a Feynman-Vernon influence functional approach. Using information theory, we define the appropriate notion of quantum limit for such an "on the fly" detector. We show that our particular detector can approach the quantum limit up to logarithms in the ratio of the measurement time over the RC relaxation time. We argue that such a weak logarithmic effect is of no practical significance. Finally we show that a two-electron interference experiment can be used to probe the detector induced decoherence., Comment: 15 pages, 7 figures, published version

Published

2007

47. The Rashba Effect within the Coherent Scattering Formalism

Author

Feve, G., Oliver, W. D., Aranzana, M., and Yamamoto, Y.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The influence of spin-orbit coupling in two-dimensional systems is investigated within the framework of the Landauer-Buettiker coherent scattering formalism. This formalism usually deals with spin-independent stationary states and, therefore, it does not include a spin-orbit contribution to the current. In this article, we will rederive the coherent scattering formalism, accounting for the changes brought about by the spin-orbit coupling. After a short review of the features of spin-orbit coupling in two-dimensional electron gases, we define the creation/annihilaton operators in the stationary states of the spin-orbit coupling Hamiltonian and use them to calculate the current operator within the Landauer-Buettiker formalism. The current is expressed as it is in the standard spin-independent case, but with the spin label replaced by a new label which we call the spin-orbit coupling label. The spin-orbit coupling effects can then be represented in a scattering matrix which relates the spin-orbit coupling stationary states in different leads. This scattering matrix is calculated in the case of a four-port beamsplitter, and it is shown to mix states with different spin-orbit coupling labels in a manner that depends on the angle between the leads. The formalism is then used to calculate the effect of spin-orbit coupling on the current and noise in two examples of electron collision., Comment: 11 pages

Published

2001

48. Violation of Kirchhoff's Laws for a Coherent RC Circuit

Author

Gabelli, J., Fève, G., Plaçais, B., Cavanna, A., Etienne, B., Jin, Y., and Glattli, D. C.

Published

2006

49. Magnetoexciton limit of quantum Hall breakdown in graphene

Author

Schmitt, A., primary, Rosticher, M., additional, Taniguchi, T., additional, Watanabe, K., additional, Berroir, J. M., additional, Ménard, G., additional, Voisin, C., additional, Fève, G., additional, Goerbig, M. O., additional, Plaçais, B., additional, and Baudin, E., additional

Published

2023

50. High-field 1/f noise in hBN-encapsulated graphene transistors

Author

Schmitt, A., primary, Mele, D., additional, Rosticher, M., additional, Taniguchi, T., additional, Watanabe, K., additional, Maestre, C., additional, Journet, C., additional, Garnier, V., additional, Fève, G., additional, Berroir, J. M., additional, Voisin, C., additional, Plaçais, B., additional, and Baudin, E., additional

Published

2023