Quantifying Spicules

TL;DR

This study uses high-resolution solar observations to identify two distinct types of spicules, revealing their different properties, regional distributions, and potential driving mechanisms, advancing understanding of solar chromosphere dynamics.

Contribution

The paper provides the first comprehensive analysis distinguishing two types of spicules and their regional behaviors using a semi-automated detection method on Hinode data.

Findings

Type II spicules are more common and faster, seen in quiet sun and coronal holes.

Type I spicules are mainly observed in active regions and show rise and fall behavior.

Properties of Type II spicules align with Rapid Blueshifted Events, suggesting a common nature.

Abstract

Understanding the dynamic solar chromosphere is fundamental in solar physics. Spicules are an important feature of the chromosphere, connecting the photosphere to the corona, potentially mediating the transfer of energy and mass. The aim of this work is to study the properties of spicules over different regions of the sun. Our goal is to investigate if there is more than one type of spicules, and how spicules behave in the quiet sun, coronal holes, and active regions. We make use of high-cadence and high-spatial resolution Ca II H observations taken by Hinode/SOT. Making use of a semi-automated detection algorithm, we self-consistently track and measure the properties of 519 spicules over different regions. We find clear evidence of two types of spicules. Type I spicules show a rise and fall and have typical lifetimes of 150-400 s and maximum ascending velocities of 15-40 km/s, while type II spicules have shorter lifetimes of 50-150 s, faster velocities of 30-110 km/s, and are not seen to fall down, but rather fade at around their maximum length. Type II spicules are the most common, seen in quiet sun and coronal holes. Type I spicules are seen mostly in active regions. There are regional differences between quiet sun and coronal hole spicules, likely attributable to the different field configurations. The properties of type II spicules are consistent with published results of Rapid Blueshifted Events (RBEs), supporting the hypothesis that RBEs are their disk counterparts. For type I spicules we find the relations between their properties to be consistent with a magnetoacoustic shock wave driver, and with dynamic fibrils as their disk counterpart. The driver of type II spicules remains unclear from limb observations.