Generic profile of a long-lived corotating interaction region and associated recurrent Forbush decrease

TL;DR

This study analyzes a long-lived corotating interaction region (CIR) from a single coronal hole over 27 rotations, examining its in situ properties and associated cosmic ray decreases to establish a generic CIR profile for future modeling.

Contribution

It provides a comprehensive statistical and superposed epoch analysis of a recurring CIR, establishing a generic profile and insights into cosmic ray modulation mechanisms.

Findings

CR count dips correlate with magnetic field peaks

Flow speed correlates with CR count profiles

Superposed epoch analysis yields a representative CIR profile

Abstract

We observe and analyse a long-lived corotating interaction region (CIR), originating from a single coronal hole (CH), recurring in 27 consecutive Carrington rotations 2057-2083 in the time period from June 2007 - May 2009. We studied the in situ measurements of this long-lived CIR as well as the corresponding depression in the cosmic ray (CR) count observed by SOHO/EPHIN throughout different rotations. We performed a statistical analysis, as well as the superposed epoch analysis, using relative values of the key parameters: the total magnetic field strength, B, the magnetic field fluctuations, dBrms, plasma flow speed, v, plasma density, n, plasma temperature, T , and the SOHO/EPHIN F-detector particle count, and CR count. We find that the mirrored CR count-time profile is correlated with that of the flow speed, ranging from moderate to strong correlation, depending on the rotation. In addition, we find that the CR count dip amplitude is correlated to the peak in the magnetic field and flow speed of the CIR. These results are in agreement with previous statistical studies. Finally, using the superposed epoch analysis, we obtain a generic CIR example, which reflects the in situ properties of a typical CIR well. Our results are better explained based on the combined convection-diffusion approach of the CIR-related GCR modulation. Furthermore, qualitatively, our results do not differ from those based on different CHs samples. This indicates that the change of the physical properties of the recurring CIR from one rotation to another is not qualitatively different from the change of the physical properties of CIRs originating from different CHs. Finally, the obtained generic CIR example, analyzed on the basis of superposed epoch analysis, can be used as a reference for testing future models.