12,788 research outputs found

    Coherent generation of the terrestrial kilometric radiation by nonlinear beatings between electrostatic waves

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    The propagation of electrostatic plasma waves in an inhomogeneous and magnetized plasma was studied. These waves, which are driven unstable by auroral beams of electrons, are shown to suffer a further geometrical amplification while they propagate towards resonances. Simultaneously, their group velocities tend to be aligned with the geomagnetic field. It is shown that the electrostatic energy tends to accumulate at, or near omega sub LH and omega sub UH, the local lower and upper hybrid frequencies. Due to this process, large amplitude electrostatic waves with very narrow spectra are observed near these frequencies at any place along the auroral field lines where intense beam driven instability takes place. These intense quasi-monochromatic electrostatic waves are shown to give rise to an intense electromagnetic radiation. Depending upon the ratio omega sub pe/omega sub ce between the electron plasma frequency and the electron gyro-frequency the electromagnetic wave can be radiated in the ordinary mode (at omega sub UH), or in the extraordinary (at 2 omega sub UH). As the ratio omega sub pe/omega sub ce tends to be rather small, it is shown that the most intense radiation should be boserved at 2 omega sub UH in the extraordinary mode

    Conception of photo-injectors for the CTF3 experiment

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    Team: G. Bienvenu, M. Bernard, B. Jacquemard, B. Mouton, J. Prevost M. Desmons, B. Mercier, C. Prevost, R. Roux, J. BrossardFor particle physics at the TeV energy scale, CERN is developing an ambitious two-beam accelerator concept for the construction of a linear collider, CLIC. This scheme is based on acceleration of the beam by 30 GHz cavities for which the RF power would be provided by the deceleration of a secondary electron beam at high intensity but low energy. To test issues in this scheme, an accelerator, the CLIC Test Facility (CTF3) is under development at CERN. LAL-Orsay is responsible for the construction of two photo-injectors for two different linacs of CTF3. The specifications for the photo-gun which will be used to produce the 30 GHz RF power are very demanding. The RF gun must provide a high quality beam composed of more than 2,000 bunches each containing 2.33 nC of charge at a repetition rate of 3 GHz. The model adopted is inspired from the CERN 2-1/2 cell type IV RF gun. It has been modified according to the results of experiments at CERN which showed a dramatic exponential growth of the residual pressure in the gun with the extracted charge. We will summarize all the studies performed on the RF design and on the beam dynamics. A comparison with RF measurements will be also shown. The constraints on the second photo-injector are less severe since it must be operated with one or 64 bunches of 0.5 nC each. It will also be a 2.5 cell gun at 3 GHz but its design will be substantially different with respect to the former. This last project has only recently begun and therefore we will limit ourselves to the presentation of the results of the RF and beam dynamics simulations

    Deep clustering: Discriminative embeddings for segmentation and separation

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    We address the problem of acoustic source separation in a deep learning framework we call "deep clustering." Rather than directly estimating signals or masking functions, we train a deep network to produce spectrogram embeddings that are discriminative for partition labels given in training data. Previous deep network approaches provide great advantages in terms of learning power and speed, but previously it has been unclear how to use them to separate signals in a class-independent way. In contrast, spectral clustering approaches are flexible with respect to the classes and number of items to be segmented, but it has been unclear how to leverage the learning power and speed of deep networks. To obtain the best of both worlds, we use an objective function that to train embeddings that yield a low-rank approximation to an ideal pairwise affinity matrix, in a class-independent way. This avoids the high cost of spectral factorization and instead produces compact clusters that are amenable to simple clustering methods. The segmentations are therefore implicitly encoded in the embeddings, and can be "decoded" by clustering. Preliminary experiments show that the proposed method can separate speech: when trained on spectrogram features containing mixtures of two speakers, and tested on mixtures of a held-out set of speakers, it can infer masking functions that improve signal quality by around 6dB. We show that the model can generalize to three-speaker mixtures despite training only on two-speaker mixtures. The framework can be used without class labels, and therefore has the potential to be trained on a diverse set of sound types, and to generalize to novel sources. We hope that future work will lead to segmentation of arbitrary sounds, with extensions to microphone array methods as well as image segmentation and other domains.Comment: Originally submitted on June 5, 201

    Reply to "Comment on `Quenches in quantum many-body systems: One-dimensional Bose-Hubbard model reexamined' ''

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    In his Comment [see preceding Comment, Phys. Rev. A 82, 037601 (2010)] on the paper by Roux [Phys. Rev. A 79, 021608(R) (2009)], Rigol argued that the energy distribution after a quench is not related to standard statistical ensembles and cannot explain thermalization. The latter is proposed to stem from what he calls the eigenstate thermalization hypothesis and which boils down to the fact that simple observables are expected to be smooth functions of the energy. In this Reply, we show that there is no contradiction or confusion between the observations and discussions of Roux and the expected thermalization scenario discussed by Rigol. In addition, we emphasize a few other important aspects, in particular the definition of temperature and the equivalence of ensemble, which are much more difficult to show numerically even though we believe they are essential to the discussion of thermalization. These remarks could be of interest to people interested in the interpretation of the data obtained on finite-size systems.Comment: 3 page

    Fast inactivation in Shaker K+ channels. Properties of ionic and gating currents.

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    Fast inactivating Shaker H4 potassium channels and nonconducting pore mutant Shaker H4 W434F channels have been used to correlate the installation and recovery of the fast inactivation of ionic current with changes in the kinetics of gating current known as "charge immobilization" (Armstrong, C.M., and F. Bezanilla. 1977. J. Gen. Physiol. 70:567-590.). Shaker H4 W434F gating currents are very similar to those of the conducting clone recorded in potassium-free solutions. This mutant channel allows the recording of the total gating charge return, even when returning from potentials that would largely inactivate conducting channels. As the depolarizing potential increased, the OFF gating currents decay phase at -90 mV return potential changed from a single fast component to at least two components, the slower requiring approximately 200 ms for a full charge return. The charge immobilization onset and the ionic current decay have an identical time course. The recoveries of gating current (Shaker H4 W434F) and ionic current (Shaker H4) in 2 mM external potassium have at least two components. Both recoveries are similar at -120 and -90 mV. In contrast, at higher potentials (-70 and -50 mV), the gating charge recovers significantly more slowly than the ionic current. A model with a single inactivated state cannot account for all our data, which strongly support the existence of "parallel" inactivated states. In this model, a fraction of the charge can be recovered upon repolarization while the channel pore is occupied by the NH2-terminus region

    Scattering by a toroidal coil

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    In this paper we consider the Schr\"odinger operator in R3{\mathbb R}^3 with a long-range magnetic potential associated to a magnetic field supported inside a torus T{\mathbb{T}}. Using the scheme of smooth perturbations we construct stationary modified wave operators and the corresponding scattering matrix S(λ)S(\lambda). We prove that the essential spectrum of S(λ)S(\lambda) is an interval of the unit circle depending only on the magnetic flux ϕ\phi across the section of T\mathbb{T}. Additionally we show that, in contrast to the Aharonov-Bohm potential in R2{\mathbb{R}}^2, the total scattering cross-section is always finite. We also conjecture that the case treated here is a typical example in dimension 3.Comment: LaTeX2e 17 pages, 1 figur
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