The intensity and evolution of the extreme storms in January 1938

TL;DR

This study analyzes the sequence and impact of extreme solar storms in January 1938, revealing their source activity, geomagnetic effects, cosmic-ray variations, and auroral extent, highlighting the complex interactions of multiple consecutive ICMEs.

Contribution

It provides a detailed reconstruction of the January 1938 storm sequence, combining historical records with analysis of solar eruptions, ICMEs, and geomagnetic responses, offering insights into storm synergy.

Findings

Three successive geomagnetic storms occurred in January 1938.

The first ICME caused the largest cosmic-ray decrease and storm sudden commencement.

Auroral boundaries extended to lower latitudes during the second and third storms.

Abstract

Major solar eruptions occasionally direct interplanetary coronal mass ejections (ICMEs) to Earth and cause significant geomagnetic storms and low-latitude aurorae. While single extreme storms are of significant threats to the modern civilization, storms occasionally appear in sequence and, acting synergistically, cause 'perfect storms' at Earth. The stormy interval in January 1938 was one of such cases. Here, we analyze the contemporary records to reveal its time series on their source active regions, solar eruptions, ICMEs, geomagnetic storms, low-latitude aurorae, and cosmic-ray (CR) variations. Geomagnetic records show that three storms occurred successively on 17/18 January (Dcx ~ -171 nT) on 21/22 January (Dcx ~ -328 nT) and on 25/26 January (Dcx ~ -336 nT). The amplitudes of the cosmic-ray variations and sudden storm commencements show the impact of the first ICME as the largest (~ 6% decrease in CR and 72 nT in SSC) and the ICME associated with the storms that followed as more moderate (~ 3% decrease in CR and 63 nT in SSC; ~ 2% decrease in CR and 63 nT in SSC). Interestingly, a significant solar proton event occurred on 16/17 January and the Cheltenham ionization chamber showed a possible ground level enhancement. During the first storm, aurorae were less visible at mid-latitudes, whereas during the second and third storms, the equatorward boundaries of the auroral oval were extended down to 40.3{\deg} and 40.0{\deg} in invariant latitude. This contrast shows that the initial ICME was probably faster, with a higher total magnitude but a smaller southward component.