H. Debrunner scite author profile

Abstract. During the solar flares on 9, 11, and 15 June 1991 the COMPTEL instrument measured extended γ-radiation in the 2.223 MeV neutron-capture line, in prompt nuclear deexcitation lines and in pion-decay radiation for several hours after the flares. The long-term time profiles can be described by a double exponential decay with decay constants on the order of 10 min for the fast and several 100 min for the slow components. We studied the 11 June 1991 flare in more detail and found that during the extended phase the accelerated proton and ion spectrum is harder, the e/p ratio is lower, and the emission profile is smoother, compared to those of the impulsive phase. Pion-decay radiation was not detected before the onset of the extended emission phase. When comparing the three flares to one another, we found a striking similarity in the time profiles of the nuclear line and the neutron capture line emission. However, the pion-decay radiation varied in intensity significantly from flare to flare. The impulsive-phase emissions of the flares show no such similarity. Our measurements indicate that the processes taking place during the extended phase differ from those during the impulsive phase, or in other γ-ray line flares. Based on these results long-term trapping of energetic particles from the impulsive phase seems unlikely, as opposed to continuous particle acceleration.

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Forbush decreases and interplanetary magnetic field disturbances: Association with magnetic clouds

Lockwood¹,

Webber²,

Debrunner³

1991

J. Geophys. Res.

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Magnetic clouds have been proposed as a mechanism to produce Forbush decreases in the cosmic radiation. We have examined the temporal association of magnetic clouds and Forbush decreases and find practically no association of the main phase of the Forbush decrease with the arrival of a magnetic cloud. On the other hand, Forbush decreases generally follow the strong interplanetary shocks which sometimes precede magnetic clouds. The main phase of the cosmic ray decrease occurs 2–5 hours after the shock and during the passage of the region in which the magnetic field is disturbed. It appears that a Forbush decrease is more likely to occur following a shock in which the magnetic field and plasma parameters are strongly enhanced. These results indicate that the decrease of the cosmic ray intensity may be produced by the smaller diffusion coefficient in the region behind the shock. The sweeping effect of the enhanced magnetic field associated with the fast shock also probably contributes to the rapid depression of the cosmic ray intensity seen in some decreases.

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Solar neutron and proton production during the 1990 May 24 cosmic-ray flare increases

Debrunner¹,

Lockwood²,

Ryan³

1993

ApJ

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The rigidity dependence of forbush decreases observed at the Earth

Lockwood¹,

Webber²,

Debrunner³

1991

J. Geophys. Res.

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The rigidity dependence of the large Forbush decreases occurring on July 23, 1981, July 11, 1982, and February 6, 1986, has been determined using neutron monitor and IMP spacecraft data which cover the energy range from about 50 MeV to 30 GeV. The contribution of solar flare protons to the lower‐energy data from the IMP cosmic ray telescopes was carefully removed. We found that the rigidity dependences of the magnitudes of the July 1981, July 1982, and February 1986 Forbush decreases for P ≥ 2 GV were given by exp (−1/P0.75), exp (−1/P0.6), and exp (−1/P1.0), respectively. For 0.5 ≤ P ≤ 2 GV the magnitude of the Forbush decreases in July 1981 and July 1982 was rigidity independent. The February 1986 event also appeared to be rigidity independent below ∼1 GV. The characteristic recovery time of these Forbush decreases was found to be not strongly rigidity dependent. These results on the rigidity dependence of Forbush decreases for 0.5 < P < 20 GV are discussed in the context of proposed models.

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H. Debrunner

Energetic Neutrons, Protons, and Gamma Rays during the 1990 May 24 Solar Cosmic‐Ray Event

Extended gamma-ray emission of the solar flares in june 1991

Forbush decreases and interplanetary magnetic field disturbances: Association with magnetic clouds

Solar neutron and proton production during the 1990 May 24 cosmic-ray flare increases

The rigidity dependence of forbush decreases observed at the Earth

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