Scaling and singularity characteristics of solar wind and magnetospheric fluctuations

Vörös, Z.; Jankovičovà, D.; Kovács, Péter

doi:10.5194/npg-9-149-2002

Cited by 31 publications

(23 citation statements)

References 63 publications

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“…As a consequence, the associated probability density functions (PDF's) are non-Gaussian. It has been shown by Vörös et al (2002) and Dorotovic and Vörös (2004) that intermittent fluctuations in the solar wind affect the geomagnetic response. By comparing solar wind data obtained from the ACE spacecraft with plasma sheet data from the Geotail mission, Dorotovic and Vörös (2004) suggested that the non-Gaussian characteristics of the PDF's of solar wind data can be interconnected to the occurrence of intermittency in the magnetic fluctuations in the plasma sheet.…”

Section: Introductionmentioning

confidence: 99%

Intermittent chaos driven by nonlinear Alfvén waves

Rempel

Chian

Preto

et al. 2004

Nonlin. Processes Geophys.

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Abstract.We investigate the relevance of chaotic saddles and unstable periodic orbits at the onset of intermittent chaos in the phase dynamics of nonlinear Alfvén waves by using the Kuramoto-Sivashinsky (KS) equation as a model for phase dynamics. We focus on the role of nonattracting chaotic solutions of the KS equation, known as chaotic saddles, in the transition from weak chaos to strong chaos via an interior crisis and show how two of these unstable chaotic saddles can interact to produce the plasma intermittency observed in the strongly chaotic regimes. The dynamical systems approach discussed in this work can lead to a better understanding of the mechanisms responsible for the phenomena of intermittency in space plasmas.

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Section: Introductionmentioning

confidence: 99%

Intermittent chaos driven by nonlinear Alfvén waves

Rempel

Chian

Preto

et al. 2004

Nonlin. Processes Geophys.

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“…This necessitates quantitative "comparative" studies of scaling in time series (e.g. Takalo and Timonen, 1998;Freeman et al, 2000;Uritsky et al, 2001;Vörös et al, 2002;Hnat et al, 2003a). Such studies can to some extent fruitfully consider the low order moments, whereas a particular difficulty for comparison of observations with models of turbulence is that the intermittency parameter in turbulence τ (2) is determined by the 6th order structure function .…”

Section: Introductionmentioning

confidence: 99%

Scaling collapse and structure functions: identifying self-affinity in finite length time series

Chapman

Hnat

Rowlands

et al. 2005

Nonlin. Processes Geophys.

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Abstract. Empirical determination of the scaling properties and exponents of time series presents a formidable challenge in testing, and developing, a theoretical understanding of turbulence and other out-of-equilibrium phenomena. We discuss the special case of self affine time series in the context of a stochastic process. We highlight two complementary approaches to the differenced variable of the data: i) attempting a scaling collapse of the Probability Density Functions which should then be well described by the solution of the corresponding Fokker-Planck equation and ii) using structure functions to determine the scaling properties of the higher order moments. We consider a method of conditioning that recovers the underlying self affine scaling in a finite length time series, and illustrate it using a Lévy flight.

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“…Recent studies on scaling and singularity characteristics of geomagnetic fluctuations into the MHD flow system, considering solar wind and ionosphere phenomena, suggest that the nearEarth magnetosphere is a non-homogenous interconnecting multi-scale environment where spatio-temporal variability is intermittent. In this inhomogeneous scenario, multifractal turbulence can coexist with coherent global processes and self-organized criticality involving the singular behavior of the energy distribution in physical space resulting in strong gradients (Vörös et al, 2002). Such strong variations constitute the intermittency pattern in the time-series, usually a measurement of the energy related to the physical quantities of the system, e.g.…”

Section: Methodsmentioning

confidence: 99%

“…A usual hypothesis is that the intermittency behavior is associated with the multifractal turbulence model (Muzy et al, 1991). This fact suggests that the fluctuations can be described by means of a multifractal scaling law which is associated with intermittency, then admitting that nonlinear and coherent processes can coexist (Vörös et al, 2002;Weygand et al, 2005;Wanliss et al, 2005). Thus, the present study deals with the multifractal analyses of low-latitude geomagnetic H -field records which is fully intermittent.…”

Section: Introductionmentioning

confidence: 99%

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Multifractal analysis of low-latitude geomagnetic fluctuations

2009

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Abstract.The technique of large deviation multifractal spectrum has shown that the high-latitude (77.5 • N, 69.2 • W) geomagnetic fluctuations can be described from direct dissipation process or loading-unloading regimes of the solar windmagnetosphere coupling. In this paper, we analyze the Hcomponent of low-latitude (22.4 • S, 43.6 • W) geomagnetic field variability observed during the month of July 2000 at the Geomagnetic Observatory, Vassouras, RJ, Brazil. The variability pattern during this period is a mixture of quiet and disturbed days including the Bastille Day intense geomagnetic storm on 15 July. Due to the complexity of this data, we pursue a detailed analysis of the geomagnetic fluctuations in different time scales including a multifractal approach using the singular power spectrum deviations obtained from the wavelet transform modulus maxima (WTMM). The results suggest, as observed from high-latitude data, the occurrence of low-latitude multifractal processes driving the intermittent coupling between the solar wind-magnetosphere and geomagnetic field variations. On finer scales possible physical mechanisms in the context of nonlinear magnetosphere response are discussed.

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Scaling and singularity characteristics of solar wind and magnetospheric fluctuations

Cited by 31 publications

References 63 publications

Intermittent chaos driven by nonlinear Alfvén waves

Intermittent chaos driven by nonlinear Alfvén waves

Scaling collapse and structure functions: identifying self-affinity in finite length time series

Multifractal analysis of low-latitude geomagnetic fluctuations

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