4,625 research outputs found

    High energy particles accelerated during the large solar flare of 1990 May 24: X/γ-ray observations

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    The PHEBUS experiment aboard GRANAT observed γ-ray line emission and γ-ray continuum above 10 MeV from the 24 May, 1990 solar flare. Observations and interpretation of the high-energy continuum have been discussed previously. Here we re-examine these, combining the PHEBUS observations above 10 MeV with calculations of the pion decay continuum to quantitatively constrain the accelerated ion energy distribution at energies above 300 MeV. The uncertainty in the determination of the level of the primary electron bremsstrahlung as well as the lack of measurements on the γ-ray emission above 100 MeV combine to allow rather a wide range of energy distribution parameters (in terms of the number of protons above 30 MeV, the spectral index of the proton distribution and the high energy cut-off of the energetic protons). Nevertheless we are able to rule out some combinations of these parameters. Using the additional information provided by the γ-ray line observations we discuss whether it is possible to construct a consistent picture of the ions which are accelerated in a wide energy range during this flare. Our findings are discussed with respect to previous works on the spectrum of energetic protons in the 10 MeV to GeV energy range

    Temporal evolution of an energetic electron population in an inhomogeneous medium: Application to solar hard X-ray bursts

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    Energetic electrons accelerated during solar flares can be studied through the hard X-ray emission they produce when interacting with the solar ambient atmosphere. In the case of the non thermal hard X-ray emission, the instanteous X-ray flux emitted at one point of the atmosphere is related to the instantaneous fast electron spectrum at that point. A hard X-ray source model then requires the understanding of the evolution in space and time of the fast particle distribution. The physical processes involved here are energy losses due to Coulomb collisions and pitch angle scattering due to both collisions and magnetic field gradients

    Comparative Analysis of Non-thermal Emissions and Study of Electron Transport in a Solar Flare

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    We study the non-thermal emissions in a solar flare occurring on 2003 May 29 by using RHESSI hard X-ray (HXR) and Nobeyama microwave observations. This flare shows several typical behaviors of the HXR and microwave emissions: time delay of microwave peaks relative to HXR peaks, loop-top microwave and footpoint HXR sources, and a harder electron energy distribution inferred from the microwave spectrum than from the HXR spectrum. In addition, we found that the time profile of the spectral index of the higher-energy (\gsim 100 keV) HXRs is similar to that of the microwaves, and is delayed from that of the lower-energy (\lsim 100 keV) HXRs. We interpret these observations in terms of an electron transport model called {\TPP}. We numerically solved the spatially-homogeneous {\FP} equation to determine electron evolution in energy and pitch-angle space. By comparing the behaviors of the HXR and microwave emissions predicted by the model with the observations, we discuss the pitch-angle distribution of the electrons injected into the flare site. We found that the observed spectral variations can qualitatively be explained if the injected electrons have a pitch-angle distribution concentrated perpendicular to the magnetic field lines rather than isotropic distribution.Comment: 32 pages, 12 figures, accepted for publication in The Astronomical Journa

    Magnitudes and temporal sequencing of load kinematics and kinetics for single-handed pulls

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    This paper provides data regarding kinematics and kinetics during single-handed, submaximal pulls about various locations in the frontal plane for three loads (6, 12 and 18% lean body mass). Pulls were executed at two relative heights (elbow and eye) through two parasagittal planes also relative to subject morphology. Results indicate that in most cases load and pull location influence the occurrence of measured kinetic variables within a pull cycle but have little effect on the magnitude of these values. Findings from this study suggest that analyses of kinematic and kinetic movement histories may be required for a better understanding of the mechanical loading profiles upon operators engaged in such manual materials handling activities

    Multifractal properties of critical eigenstates in two-dimensional systems with symplectic symmetry

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    The multifractal properties of electronic eigenstates at the metal-insulator transition of a two-dimensional disordered tight-binding model with spin-orbit interaction are investigated numerically. The correlation dimensions of the spectral measure D~2\widetilde{D}_{2} and of the fractal eigenstate D2D_{2} are calculated and shown to be related by D2=2D~2D_{2}=2\widetilde{D}_{2}. The exponent η=0.35±0.05\eta=0.35\pm 0.05 describing the energy correlations of the critical eigenstates is found to satisfy the relation η=2D2\eta=2-D_{2}.Comment: 6 pages RevTeX; 3 uuencoded, gzipped ps-figures to appear in J. Phys. Condensed Matte

    Phase rigidity breaking in open Aharonov-Bohm ring coupled to a cantilever

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    The conductance and the transmittance phase shifts of a two-terminal Aharonov-Bohm (AB) ring are analyzed in the presence of mechanical displacements due to coupling to an external can- tilever. We show that phase rigidity is broken, even in the linear response regime, by means of inelastic scattering due to phonons. Our device provides a way of observing continuous variation of the transmission phase through a two-terminal nano-electro-mechanical system (NEMS). We also propose measurements of phase shifts as a way to determine the strength of the electron-phonon coupling in NEMS.Comment: 7 pages, 8 figure

    Critical regime of two dimensional Ando model: relation between critical conductance and fractal dimension of electronic eigenstates

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    The critical two-terminal conductance gcg_c and the spatial fluctuations of critical eigenstates are investigated for a disordered two dimensional model of non-interacting electrons subject to spin-orbit scattering (Ando model). For square samples, we verify numerically the relation σc=1/[2π(2D(1))]e2/h\sigma_c=1/[2\pi(2-D(1))] e^2/h between critical conductivity σc=gc=(1.42±0.005)e2/h\sigma_c=g_c=(1.42\pm 0.005) e^2/h and the fractal information dimension of the electron wave function, D(1)=1.889±0.001D(1)=1.889\pm 0.001. Through a detailed numerical scaling analysis of the two-terminal conductance we also estimate the critical exponent ν=2.80±0.04\nu=2.80\pm 0.04 that governs the quantum phase transition.Comment: IOP Latex, 7 figure

    Localization Transition in Multilayered Disordered Systems

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    The Anderson delocalization-localization transition is studied in multilayered systems with randomly placed interlayer bonds of density pp and strength tt. In the absence of diagonal disorder (W=0), following an appropriate perturbation expansion, we estimate the mean free paths in the main directions and verify by scaling of the conductance that the states remain extended for any finite pp, despite the interlayer disorder. In the presence of additional diagonal disorder (W>0W > 0) we obtain an Anderson transition with critical disorder WcW_c and localization length exponent ν\nu independently of the direction. The critical conductance distribution Pc(g)P_{c}(g) varies, however, for the parallel and the perpendicular directions. The results are discussed in connection to disordered anisotropic materials.Comment: 10 pages, Revtex file, 8 postscript files, minor change

    Classifying occupational exposure risks and recommendations for their control in container-based sanitation systems

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    This practice paper concerns the management of occupational exposure risks during the operation of container-based sanitation (CBS) systems. The paper reports on findings based on three different CBS systems. An exposure risk assessment was conducted in each case study following a methodology adapted from the WHO Sanitation Safety Planning (SSP) Framework. The specific methods of data collection comprised a risk assessment workshop, as well as in-depth interviews and sanitary surveys to support and explain the findings from the risk assessment workshops. The analysis of the occupational exposure risks classified exposure risks into four categories of ‘drivers’ of exposure risk. These ‘drivers’ were supported by relevant secondary literature of exposure risk studies. The classification of hazardous events and exposure risks in CBS systems recognized: (1) the role of technical design and maintenance and condition of facilities, as well as manual aspects of labour; followed by (2) human behaviour; (3) system performance; and (4) physical environment. This classification is expected to simplify the exposure risk management process and provides a framework for the subsequent identification and management of occupational exposure in CBS systems. The framework is an additional tool within the sanitation safety planning toolkit to measure and manage exposure risks and thereby ensure safe sanitation performance. This research addresses a current knowledge gap in occupational exposure risks in CBS systems. The integration and use of these results in an adapted SSP framework may build a stronger business case for the adoption of CBS systems in city-wide urban sanitation sector planning
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