J. A. Lockwood scite author profile

The experimental observations of Forbush decreases in recent years are reviewed and related to different theoretical models which have been proposed. The observational data from both ground-based and spacecraft experiments were selected to illustrate the important characteristics of Forbush decreases. The form of the rigidity dependence of the cosmic-ray modulation during the decreases and effects of the geomagnetic field upon the magnitude of the decreases are discussed. Recent results to deduce the cosmic-ray flow patterns from the observed anisotropies during the decreases are presented. Other features such as differences in onset times, recovery times, precursory increases are discussed. In considering the theoretical models particular emphasis is placed upon the agreement of the predictions of the model with the experimental observations. A theoretical model is suggested which is not original but represents a synthesis of several models previously proposed. Future important measurements and analyses necessary to an understanding of Forbush decreases are outlined.

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Voyager and Pioneer spacecraft measurements of cosmic ray intensities in the outer heliosphere: Toward a new paradigm for understanding the global solar modulation process: 1. Minimum solar modulation (1987 and 1997)

Webber¹,

Lockwood²

2001

J. Geophys. Res.

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Abstract. Using IMP, Voyager, and Pioneer spacecraft data, we have derived radial intensity profiles of cosmic rays in the heliosphere out to •70 AU as fractions of the expected interstellar intensities for five particle energies/species during the minimum solar modulation periods of 1987 and 1997. These radial profiles exhibit a markedly different behavior in the two periods of opposite solar magnetic polarity. In the negative polarity period (1987) the radial profiles for the highest-rigidity particles extrapolate to the interstellar (IS) intensity at approximately the estimated location of heliospheric termination shock (TS) at 85-90 AU. The lower-rigidity particle intensities extrapolate to only 0.45-0.60 of the IS intensity at this same location, indicating that a large part of the residual solar modulation for these particles at this time takes place at or beyond the location of the TS. In the 1997 positive polarity time period the fraction of the overall modulation that is occurring between the Earth and the TS is now much smaller, and since the intensity at the Earth is the same in both cycles, the consequence is that the extrapolated radial intensities at the TS location are now only 0.50 (at the highest rigidities) to 0.17 (at the lowest rigidities) of the respective IS intensities. Thus, at this time of minimum modulation most of the residual modulation apparently is taking place near to or beyond the TS. Also, the ratio of the fraction of the total residual modulation that is taking place between the Earth and the TS and that taking place beyond the TS changes dramatically between positive and negative modulation cycles. Viewed in this new way, contemporary modulation models including drifts, when they are assumed to occur within the TS, do not provide a satisfactory quantitative explanation of the modulation that is taking place at the minimum of solar activity. These models do not predict the large amount of modulation taking place near or beyond the termination shock. This outer heliospheric modulation dominates the overall residual modulation at low energies and is more effective in positive solar magnetic polarity periods. A new paradigm seems to be needed to interpret this large modulation that is taking place in the outer heliosphere.

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

Debrunner

Lockwood

Barat

et al. 1997

ApJ

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Differential response and specific yield functions of cosmic-ray neutron monitors

Lockwood¹,

Webber²

1967

J. Geophys. Res.

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From the recent neutron monitor latitude survey by H. Carmichael and from the primary spectrum measurements by W. Webber both at solar minimum, we have deduced new differential response and specific yield functions of cosmic‐ray neutron monitors located at sea level and mountain elevations with vertical cutoff rigidities in the interval 0.7 < Pc < 10 Gv. The differential response functions at sea level are larger than the previously calculated values at rigidities P < 3 Gv. The proton specific yield function at sea level is obtained and can be represented by KP+2.6 for 2.5 < P < 6 Gv. The relative contributions of primary nuclei with Z ≥ 2 to the counting rate of a sea‐level neutron monitor as a function of Pc are evaluated. The change in the differential response functions between 1963 and 1965 has been used to determine the change in the primary differential cosmic‐ray spectrum. The decrease in the observed differential primary spectrum agrees well with the decrease in the neutron differential response function in the rigidity range where they can be compared.

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J. A. Lockwood

Instrument description and performance of the Imaging Gamma-Ray Telescope COMPTEL aboard the Compton Gamma-Ray Observatory

Forbush decreases in the cosmic radiation

Voyager and Pioneer spacecraft measurements of cosmic ray intensities in the outer heliosphere: Toward a new paradigm for understanding the global solar modulation process: 1. Minimum solar modulation (1987 and 1997)

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

Differential response and specific yield functions of cosmic-ray neutron monitors

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