OSO-7 observations of solar x-rays in the energy range 10?100 keV

Datlowe, D. W.; Elcan, M. J.; Hudson, H. S.

doi:10.1007/bf00154978

Cited by 136 publications

(69 citation statements)

References 19 publications

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“…The most important result of the over-the-limb burst characteristics is that the fraction of the bursts which have a non-thermal component is 2/3, exactly the same as found for the 122 X-ray bursts studied in Datlowe et al (1974b). What is more, of the eight.bursts with expected locations with 0 greater than 1000, corresponding to minimum visible heights 4 5 from 10 to 10 km, five exhibit a detectable non-thermal component.…”

Section: Discussionsupporting

confidence: 67%

“…The height above which X-ray emission is observed can be expressed as In addition to those events, we have selected a set of 37 non-thermal 'limb' bursts identified from SGD as coming from flares located between 600 < 0 <900. As a reference for comparison to these, we used the same-set of 59 non-thermal events at 0O 0 <600 as used in Datlowe et al (1974b), hereafter identified as 'center' events.…”

Section: Data Selectionmentioning

confidence: 99%

“…For 50 events of 122 in Datlowe et al (1974b), the correlation between T and has been determined; the correlation coefmax ficient is -0.6. The corresponding coefficient of correlation for 39 limb and over-the-limb events is -0.4.…”

Section: Ii) the Cooling Properties Of The Thermal X-ray Burstsmentioning

confidence: 99%

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X-Ray bursts from solar flares behind the limb

Roy

Datlowe

1975

Sol Phys

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From the UCSD OSO-7 X-ray experiment data, we have identified 54 X-ray bursts with 5.1-6.6 keV flux greater 3-2 -1 -1 than 10 photons cm sec keV which were not accompanied by visible He flare on the solar disk. By studying OSO-5 X-ray spectroheliograms, He activity at the limb and the emergence and disappearance of sunspot groups at the limb, we found 17 active centers as likely seats of the X-ray bursts beyond the limb. We present the analysis of 37 X-ray bursts and their physical parameters. We compare our results with those published by Datlowe et al. (1974 a and b) for disk events.The distributions of maximum temperature, maximum emission measure, and characteristic cooling time of the over-the-limb events do not significantly differ from those of disk events. We show that of conduction and.radiation, the former is the dominant cooling mechanism for the hot flare plasma. Since the disk and over-the-limb bursts are similar, we conclude that the scale height for X-ray emission in the 5-10 keV range is large and is consistent with that of Catalano and Van Allen (1973), for primarily 1-3 keVy emission, 11,000 km.Twenty-five or about 2/3 of the over-the-limb events had a nonthermal component. The distribution of peak 20 keV flux is not significantly different from that of disk events.However, the spectral index at the time of maximum flux is significantly different for events over the limb and for events near the center of the disk; the spectral index for over-the-limb events is larger by about Ay= 3/4. If hard X-ray emission came only from localized sources low in the chromosphere we would expect that hard X-ray emission would be occulted over the limb; on the contrary, the observations show that the fraction of soft X-ray bursts which have a nonthermal component is the same on and off of the disk.Thus hard X-ray emission over extended regions is indicated.

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Section: Discussionsupporting

confidence: 67%

Section: Data Selectionmentioning

confidence: 99%

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X-Ray bursts from solar flares behind the limb

Roy

Datlowe

1975

Sol Phys

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“…Observations show that the distribution of solar flare hard X-ray bursts is a power law in peak photon flux with logarithmic slope near 1.8 (Datlowe et al 1974;Dennis 1985;Lin et al 1984;Einaudi & Velli 1999;Charbonneau et al 2001). The powerlaw index of the distribution is independent of solar cycle.…”

Section: Introductionmentioning

confidence: 99%

Self-Organized Braiding and the Structure of Coronal Loops

Berger

Asgari-Targhi

2009

ApJ

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The Parker model for heating of the solar corona involves reconnection of braided magnetic flux elements. Much of this braiding is thought to occur at as yet unresolved scales, for example, braiding of threads within an extremeultraviolet or X-ray loop. However, some braiding may be still visible at scales accessible to TRACE or Hinode. We suggest that attempts to estimate the amount of braiding at these scales must take into account the degree of coherence of the braid structure. In this paper, we examine the effect of reconnection on the structure of a braided magnetic field. We demonstrate that simple models of braided magnetic fields which balance the input of topological structure with reconnection evolve to a self-organized critical state. An initially random braid can become highly ordered, with coherence lengths obeying power-law distributions. The energy released during reconnection also obeys a power law. Our model gives more frequent (but smaller) energy releases nearer to the ends of a coronal loop.

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“…The results are power-laws, f (E) ∼ E −α , distributions with indexes α around 1.8 (Datlowe et al, 1974;Lin et al, 1984;Dennis, 1985;Crosby et al, 1993Crosby et al, , 1998Aschwanden et al, 2001). The later authors also present a substantial investigation of the total energy in the flare electrons observed in hard X-Ray bremsstrahlung, finding α = 1.5 ± 0.02.…”

Section: Introductionmentioning

confidence: 90%

Classification of probability densities on the basis of Pearson’s curves with application to coronal heating simulations

Podladchikova

Lefebvre²,

Krasnoselskikh³

et al. 2003

Nonlin. Processes Geophys.

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Abstract. An important task for the problem of coronal heating is to produce reliable evaluation of the statistical properties of energy release and eruptive events such as microand nanoflares in the solar corona. Different types of distributions for the peak flux, peak count rate measurements, pixel intensities, total energy flux or emission measures increases or waiting times have appeared in the literature. This raises the question of a precise evaluation and classification of such distributions. For this purpose, we use the method proposed by K. Pearson at the beginning of the last century, based on the relationship between the first 4 moments of the distribution. Pearson's technique encompasses and classifies a broad range of distributions, including some of those which have appeared in the literature about coronal heating. This technique is successfully applied to simulated data from the model of Krasnoselskikh et al. (2002). It allows to provide successful fits to the empirical distributions of the dissipated energy, and to classify them as a function of model parameters such as dissipation mechanisms and threshold.

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OSO-7 observations of solar x-rays in the energy range 10?100 keV

Cited by 136 publications

References 19 publications

X-Ray bursts from solar flares behind the limb

X-Ray bursts from solar flares behind the limb

Self-Organized Braiding and the Structure of Coronal Loops

Classification of probability densities on the basis of Pearson’s curves with application to coronal heating simulations

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