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01 Sep 2020, 9:08 am
According to Wikipedia:
Quote:
The September 1859 geomagnetic storm (also known as the Carrington Event) was a powerful geomagnetic storm during solar cycle 10 (1855–1867). A solar coronal mass ejection (CME) hit Earth's magnetosphere and induced the largest geomagnetic storm on record on September 1–2, 1859. The associated "white light flare" in the solar photosphere was observed and recorded by British astronomers Richard C. Carrington and Richard Hodgson. The storm caused strong auroral displays and wrought havoc with telegraph systems. The now-standard unique IAU identifier for this flare is SOL1859-09-01.
A solar storm of this magnitude occurring today would cause widespread electrical disruptions, blackouts and damage due to extended outages of the electrical grid.
A solar storm of this magnitude occurring today would cause widespread electrical disruptions, blackouts and damage due to extended outages of the electrical grid.
IMHO if the Carrington Event occurred today, it could produce massive electrical blackouts that could last for a year over vast regions of the U.S. Living without electricity for a day or two is an inconvenience. But in our modern world, living without electricity for a year would be cataclysmic for most people.
According to SpaceWeather.com of 1 September 2020:
On Sept. 1st, 1859, the most ferocious solar storm in recorded history engulfed our planet. It was "the Carrington Event," named after British scientist Richard Carrington, who witnessed the flare that started it. The storm rocked Earth's magnetic field, sparked auroras over Cuba, the Bahamas and Hawaii, set fire to telegraph stations, and wrote itself into history books as the Biggest. Solar. Storm. Ever.
But, sometimes, what you read in history books is wrong.
"The Carrington Event was not unique," says Hisashi Hayakawa of Japan's Nagoya University, whose recent study of solar storms has uncovered other events of comparable intensity. "While the Carrington Event has long been considered a once-in-a-century catastrophe, historical observations warn us that this may be something that occurs much more frequently."
To generations of space weather forecasters who learned in school that the Carrington Event was one of a kind, these are unsettling thoughts. Modern technology is far more vulnerable to solar storms than 19th-century telegraphs. Think about GPS, the internet, and transcontinental power grids that can carry geomagnetic storm surges from coast to coast in a matter of minutes. A modern-day Carrington Event could cause widespread power outages along with disruptions to navigation, air travel, banking, and all forms of digital communication.
Many previous studies of solar superstorms leaned heavily on Western Hemisphere accounts, omitting data from the Eastern Hemisphere. This skewed perceptions of the Carrington Event, highlighting its importance while causing other superstorms to be overlooked.
A good example is the great storm of mid-September 1770, when extremely bright red auroras blanketed Japan and parts of China. Captain Cook himself saw the display from near Timor Island, south of Indonesia. Hayakawa and colleagues recently found drawings of the instigating sunspot, and it is twice the size of the Carrington sunspot group. Paintings, dairy entries, and other newfound records, especially from China, depict some of the lowest-latitude auroras ever, spread over a period of 9 days.
"We conclude that the 1770 magnetic storm was comparable to the Carrington Event, at least in terms of auroral visibility," wrote Hayakawa and colleagues in a 2017 Astrophysical Journal Letter. Moreover, "the duration of the storm activity was much longer than usual."
Hayakawa's team has delved into the history of other storms as well, examining Japanese diaries, Chinese and Korean government records, archives of the Russian Central Observatory, and log-books from ships at sea--all helping to form a more complete picture of events.
They found that superstorms in February 1872 and May 1921 were also comparable to the Carrington Event, with similar magnetic amplitudes and widespread auroras. Two more storms are nipping at Carrington's heels: The Quebec Blackout of March 13, 1989, and an unnamed storm on Sept. 25, 1909, were only a factor of ~2 less intense. (Check Table 1 of Hayakawa et al's 2019 paper for details.)
"This is likely happening much more often than previously thought," says Hayakawa.
Chinese report of a giant naked-eye sunspot group on February 9, 1872.
Are we overdue for another Carrington Event? Maybe. In fact, we might have just missed one.
In July 2012, NASA and European spacecraft watched an extreme solar storm erupt from the sun and narrowly miss Earth. "If it had hit, we would still be picking up the pieces," announced Daniel Baker of the University of Colorado at a NOAA Space Weather Workshop 2 years later. "It might have been stronger than the Carrington Event itself."
History books, let the re-write begin.
