Decayless oscillations in solar coronal bright points

TL;DR

This study reports the first detection of decayless kink oscillations in solar coronal bright points, revealing their commonality and potential for coronal seismology, using high-resolution imaging and motion magnification techniques.

Contribution

It is the first to identify decayless oscillations in CBPs and analyze their properties, advancing understanding of small-scale coronal dynamics.

Findings

Decayless oscillations are common in CBPs.

Oscillation periods range from 1 to 8 minutes.

Average displacement amplitude is 0.07 Mm.

Abstract

Decayless kink oscillations of solar coronal loops (or decayless oscillations for short) have attracted great attention since their discovery. Coronal bright points (CBPs) are mini-active regions and consist of loops with a small size. However, decayless oscillations in CBPs have not been widely reported. In this study, we identified this kind of oscillations in some CBPs using 171 \AA\, images taken by the Atmospheric Imaging Assembly (AIA) onboard the Solar Dynamics Observatory (SDO). After using the motion magnification algorithm to increase oscillation amplitudes, we made time-distance maps to identify the oscillatory signals. We also estimated the loop lengths and velocity amplitudes. We analysed 23 CBPs, and found 31 oscillation events in 16 of them. The oscillation periods range from 1 to 8 minutes (on average about 5 minutes), and the displacement amplitudes have an average value of 0.07 Mm. The average loop length and velocity amplitude are 23 Mm and 1.57 \kms, respectively. Relationships between different oscillation paraments are also examined. Additionally, we performed a simple forward model to illustrate how these sub-pixel oscillation amplitudes (less than 0.4 Mm) could be detected. Results of the model confirm the reliability of our data processing methods. Our study shows for the first time that decayless oscillations are common in small-scale loops of CBPs. These oscillations allow for seismological diagnostics of the Alfv\'{e}n speed and magnetic field strength in the corona.