Active region

Region numbers

Newly observed active regions on the solar disk are assigned 4-digit region numbers by the Space Weather Prediction Center (SWPC) on the day following the initial observation. The region number assigned to a particular active region is one added to the previously assigned number. For example, the first observation of active region 8090, or AR8090, was followed by AR8091.

According to the SWPC, a number is assigned to a region if it meets at least one of the following criteria:

1. It contains a sunspot group of class C or larger based on the Modified Zurich Class sunspot classification system.
2. It contains a sunspot group of class A or B confirmed by at least two observers, preferably with observations more than one hour apart.
3. It has produced a solar flare with an X-ray burst.
4. It contains plage with a white-light brightness of at least 2.5 (on a linear scale 1-5, 5=flare) and has an extent of at least five heliographic degrees.
5. It contains plage that is bright near the west limb and is suspected of growing.

The region numbers reached 10,000 in July 2002. However, the SWPC continued using 4-digits, with the inclusion of leading zeros.

Magnetic field

Mount Wilson magnetic classification

The Mount Wilson magnetic classification system, also known as the Hale magnetic classification system, is a method of classifying the magnetic field of active regions. It was first introduced in 1919 by George Ellery Hale and coworkers working at the Mount Wilson Observatory. It originally included only the α, β, and γ magnetic classifications, but it was later modified by H. Künzel in 1965 to include the δ qualifier.

Sunspots

Main article: Sunspot

The strong magnetic flux found in active regions is often strong enough to inhibit convection. Without convection transporting energy from the Sun's interior to the photosphere, surface temperature decreases along with the intensity of emitted black body radiation. These areas of cooler plasma are known as sunspots, and often appear in groups. However, not all active regions possess sunspots.

Magnetic flux emergence

Active regions form through the process of magnetic flux emergence, during which magnetic fields generated by the solar dynamo emerge from the solar interior.

Upflow region

Analysis of Doppler velocity maps from the Hinode/EIS instrument, which observe the solar corona in specific spectral lines like FeXII, shows that at the edges of active regions on the Sun, there are always areas where plasma (hot, ionized gas) flows upward from the corona. These upward flows appear as blue-shifts in the Doppler velocity images. These regions of upflow are located where the Sun’s magnetic field lines are open—meaning they extend outward into space—and this connection seems to help drive the upflows.

The upflow regions could be the sources of the slow solar wind, a stream of charged particles that flows constantly from the Sun into space. The upflow areas tend to form early in the development of an active region and persist throughout its lifetime.

However, the exact reasons why these upflows occur are still not fully understood. Several hypothesis are being explored, such as waves traveling through the corona or magnetic reconnection—where magnetic field lines break and reconnect—in the active region’s core with open magnetic field lines. It’s also possible that multiple processes work together to create these upward flows at the same time.

References

References

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