蜜桃恋人

What is the Solar Cycle and How Long Does It Last?

Primary Image
The Solar Cycle over the years
Caption

The solar cycle from 2010 to 2020, viewed from spacecraft.

Photo Credit
Dan Seaton/European Space Agency

Learn all about the 11-year solar cycle and why it matters

No content available.
Body

Our Sun goes through what we call a 鈥渟olar cycle鈥 roughly every 11 years. During this time, the Sun鈥檚 magnetic field completely flips! Learn all about the solar cycle, what causes it, why it lasts this long, and how it affects weather and life on Earth.

What is the Solar Cycle?

A new solar cycle comes roughly every 11 years. Over the course of this cycle, the Sun will transition from a period of low solar activity to stormy, high activity and then back to low activity again. 

The solar activity is largely determined by the number and size of sunspots on the surface of the Sun. These are dark areas are associated with greater concentrations of magnetic activity.

A massive sunspot captured on Oct. 23, 2014. Ten Earth鈥檚 could be laid across its diameter. Credit: NASA/SDO

When the Sun is mid-cycle and reaches its peak, the Sun鈥檚 north and south poles flip! The south magnetic pole switches to north and vice versa. The change in polarity and reversal of the magnetic field has happened, on average, every 11 years over the past centuries. 

Solar Cycle Sunspot Progression

Note the progression of sunspot numbers in a solar cycle.

How Long is a Solar Cycle?

As mentioned above, the average length of a solar cycle is 11 years. However, it has been as short as eight years and as long as 14 years. 

  • At the beginning of the 11-year cycle, there are no or few sunspots and it鈥檚 called the 鈥渟olar minimum.鈥 
  • At mid-cycle, the Sun鈥檚 sunspots peak and build to a very active, stormy 鈥渟olar maximum.鈥 This is when the north and south poles of the Sun flip!
  • At the end of the cycle, the solar activity fades and we reach the 鈥渟olar minimum鈥 again. A new solar cycle begins.
This split image shows solar maximum (April 2014) versus solar minimum (December 2019) which began Solar Cycle 25.
Credits: NASA/SDO

What Causes the Cycle of Solar Activity?

To understand a solar cycle, it鈥檚 important to understand the Sun鈥檚 behavior. Our star is a glowing ball of electrically-charged gas. The Sun鈥檚 high temperatures causes these electrically-charged gases to constantly move around the surface of the Sun. 

Similar to Earth, the Sun has a north and a south magnetic pole. Because of the Sun鈥檚 magnetic nature, the Sun鈥檚 gases constantly gets tangled, stretched, and twisted. Imagine a rubber band that鈥檚 getting so stretched, it鈥檚 about to snap! This is why the Sun re-organizes its inner magnetic fields and changes polarity at its most dynamic point.

Sunspots, Solar Flares, and CMEs

Solar activity isn鈥檛 just sunspots but also solar flares and coronal mass ejections (CMEs). Both tend to occur near sunspot groups when the Sun is more active. Naturally, all of this solar activity coincide with solar maximum.  Here are brief definitions: 

Sunspots: The black regions on the surface of the Sun are called sunspots; in these areas, magnetic fields are particularly strong. This is indicative of stormy weather on the Sun and a lot of active magnetic activity beneath the surface. More sunspots means more solar activity.  

The dark spots are cooler than the surrounding areas. Think of them as caps to a magnetic storm that is brewing just below the solar surface. The Sun鈥檚 magnetic fields are moving around, getting twisted and concentrated in these regions.  See our article which further explains sunspots.

Solar Flares: Associated with sunspots are flashes of light on the Sun, called solar flares. Occasionally, when powerful magnetic fields reconnect, they explode and break through the Sun鈥檚 surface! There is a sudden burst light energy and X-rays. 

We classify flares according to their strength. The smallest ones are B-class, followed by C, M, and X, the largest. M-class flares can cause brief radio blackouts at the poles and minor radiation storms that might endanger astronauts.

Coronal mass ejections (CMEs): Sometime the Sun erupts, hurling large pieces of magnetic energy into space at speeds up to several million mph. Other solar events include solar wind streams that come from the coronal holes on the Sun and solar energetic particles that are primarily released by CMEs. 


Video: Coronal mass ejection, or CME, traveled away from the sun at over 900 miles per second. Credit: NASA SDO and SOHO.

How Does Solar Activity Affect Earth?

Space weather that affects Earth is not uncommon, which is why scientists track the Sun鈥檚 activity just as they might Earth鈥檚 weather and climate. 

1. Solar storms can affect electrical power grids, satellites, GPS on aircraft, radio communications, and more. As Earth is more dependent on technology, this can be concerning. Large solar flares have the potential to cause billions of dollars in damage to the world鈥檚 high-tech infrastructure.

  • For example, in January of 2022, massive solar storms destroyed 38 of the 49 Starlink satellites launched by SpaceX.

2. When the Sun is quiet, weak solar wind allows more galactic cosmic rays into the inner solar system. This can cause radiation hazards for astronauts. Even airline pilots and crew can get a higher dose of radiation during solar storms.

3. On the positive side, big solar eruptions cause the auroras, known as the Northern Lights in our hemisphere. Those gorgeous, shimmering bands of colors happen when the Sun erupts with a coronal mass ejection. 

  • The energized particles or what we call 鈥渟olar wind鈥 reach Earth鈥檚 magnetic field and interact with the gases in the atmosphere to create dancing colors in the sky.
  • Auroras are usually visible in the northern tier U.S. and in Canada, but high solar activity can occasionally cause auroras to reach our southern states!

4. Finally, the Sun鈥檚 activity also affects Earth鈥檚 climate. History has shown us that long-term periods of global cold, rainfall, drought, and other weather shifts have been influenced by solar cycle activity.

  • For example, times of depressed solar activity seem to correspond with times of global cold in history. The most famous example is the 鈥淟ittle Ice Age.鈥
frozen-thames.jpg
Painting by Abraham Hondius, 鈥淭he Frozen Thames, looking East towards towards Old London Bridge,鈥 1677. Image credit: Museum of London.

The Maunder Minimum and the 鈥淟ittle Ice Age鈥 

  • Between 1645 and 1715鈥攄uring what we now call the 鈥淢aunder Minimum鈥濃攕unspots were exceedingly rare.
  • Specifically, there were only about 50 sunspots (instead of the usual 40 to 50 thousand) and harsh winters.
  • For 70 years, temperatures dropped by 1.8 to 2.7 degrees Fahrenheit. 
  • Seven decades of freezing weather, corresponding with the coldest period of the Little Ice Age, led to shorter seasons and ultimately food shortages.

Conversely, times of increased solar activity have corresponded with global warming. During the 12th and 13th centuries, the Sun was active, and the European climate was quite mild.

Experts do not know for certain, however, what caused the Little Ice Age; theories suggest that it was likely due to a combination of events. Some scientists are researching other factors, such as heightened volcanic activity, that corresponded with the time of the Maunder Minimum.

What Solar Cycle Are We In Now?

We are currently in Solar Cycle 25, which started in December 2019. Record-keeping of solar cycles began in 1755 with Solar Cycle 1.

Some cycles have maximums with lots of sunspots and activity. Other cycles can have very few sunspots. Cycle 24 was a very quiet cycle which little solar activity. 

As the cycles can overlap, it can be challenging to predict when a new solar cycle begins. However, there are some clues.

  • For example, sunspots tend to form nearer the Sun鈥檚 equator as the cycle winds down (and at higher latitudes when a new cycle begins). 
  • Scientists measure solar cycles by keeping track of the number of sunspots appearing on the Sun鈥檚 surface as well as noting the location.
  •  A new solar cycle is considered to have begun when sunspots group at higher latitudes with the magnetic polarities of the leading spots opposite that of the previous cycle. 

Will Solar Cycle 25 be quiet or wild? See Solar Cycle 25 Predictions.

About The Author

Catherine Boeckmann

Catherine Boeckmann loves nature, stargazing, and gardening so it鈥檚 not surprising that she and The Old Farmer鈥檚 蜜桃恋人 found each other. She leads digital content for the 蜜桃恋人 website, and is also a certified master gardener in the state of Indiana. Read More from Catherine Boeckmann