Space Weather - The Carrington Event

In August of 1859, during historic Solar Cycle 10, something very strange began to happen. The Sun, as it neared solar max, grew unusually active. It produced prolific numbers of sunspots and flares, some of which were visible to the naked eye. This continued through the end of the month, until, just before noon on September 1, British astronomer Richard Carrington, just 33 and already acknowledged as one of England's premier solar astronomers, observed an incredibly brilliant solar flare – a flare that was easily visible to the naked eye. In later times, this single flare became known as The Carrington Super-Flare. In his own words from his scientific records:

“...Within the area of the great north group [of sunspots]...two patches of intensely bright and white light broke out...My first impression was that by some chance a ray of light had penetrated a hole in the [projection] screen...for the brilliancy was fully equal to that of direct sun-light; but by at once interrupting the current observation, and causing the image to move by turning the R.A. [right ascension, an astronomical coordinate akin to longitude] handle, I saw I was an unprepared witness to a very different affair...The instant of the first outburst was not 15 seconds different from 11h 18m Greenwich mean time, and 11h 23m was taken for the time of disappearance [from the telescope's view]. In this lapse of 5 minutes, the two patches of light traversed a space of about 35,000 miles...”

British amateur astronomer Richard Hodgeson also observed it; Balfour Steward at the Kew Observatory noted a “crochet” effect on the observatory's magnetometer. (A “crochet” is also sometimes called a Sudden Ionospheric Disturbance, or SID. It is when a solar event produces an abnormally high plasma density – remember, plasma is like the stuff in your fluorescent lights – in one layer of the ionosphere. This in turn creates literal electric currents running through the ionosphere, which magnetometers pick up. It creates something of an invisible lacy pattern in the atmosphere, hence, I suppose, the term “crochet.”)

And all of the previous flares and coronal mass ejections had fairly effectively cleared the interplanetary medium between the Sun and Earth.

The enormous coronal mass ejection produced by the super-flare slammed into Earth in only 17 hours.

The resulting effects lasted several days.

What kind of effects?

Worldwide aurorae for starters. These aurorae were most noted in the Caribbean, where they had never been seen before. Colorado gold miners, awakened by the brightening skies, got up and began cooking their breakfasts, because they thought it was dawn. In Europe and the northeastern United States, newspapers could be read by the light of the aurorae.

Speaking of newspapers, the Baltimore American and Commercial Advisor spoke of the ongoing event in poetic terms. “Those who happened to be out late on Thursday night had an opportunity of witnessing another magnificent display of the auroral lights. The phenomenon was very similar to the display on Sunday night, though at times the light was, if possible, more brilliant, and the prismatic hues more varied and gorgeous. The light appeared to cover the whole firmament, apparently like a luminous cloud, through which the stars of the larger magnitude indistinctly shone. The light was greater than that of the moon at its full, but had an indescribable softness and delicacy that seemed to envelop everything upon which it rested. Between 12 and 1 o'clock, when the display was at its full brilliancy, the quiet streets of the city resting under this strange light, presented a beautiful as well as singular appearance.”

Those dealing in the business of telegraphy did not think so highly of the display. The incredibly intense event, a maximal G5 and S5 by any definition, created induced currents in telegraph wires that were simply impossible to control. Lines and pylons threw sparks, telegraph batteries were blown, telegraphers received severe shocks, and telegraph “flimsy” paper burst into flames.

And yet some telegraph systems continued to function, despite having no batteries to power them. The induced current was simply that strong.

This was the Carrington Event, the most powerful solar/geomagnetic storm ever to occur in recorded history. It was before the advent of electricity, or electronics, or integrated grids and networks, save for telegraph systems, with which it wreaked havoc. Imagine what effect it would have today.

Dibs on the story.    ;-)

-Stephanie Osborn

http://www.stephanie-osborn.com

Solar, Space, and Geomagnetic Weather, Part 1

A lot of my friends and fans over on Facebook have become followers of my solar and aurora alerts there, and it has been suggested that I make this a regular part of my blog, so I thought I'd explain what it is and why it's important.

All three - solar weather, space weather, and geomagnetic weather - are interconnected. This is because the Sun has a magnetic field that extends far past the Earth, and so the Earth's magnetic field interacts with it. "Space Weather" is essentially a term for the conditions of space in the general vicinity of Earth, but not necessarily inside the Earth's magnetic field.

We are also sitting inside the atmosphere of the Sun, which is called the corona. It generates a wind, usually coming out from the Sun and spiraling away – yeah, the “solar wind.” Granted, the corona isn't very dense, but it's dense enough to create some effects, and we're working on using it to our benefit, like in solar sails and such, which can use the solar wind as much as light pressure (different blog post) to maneuver around the Solar System like the spaceborne clipper ships of old.

But when the Sun gets...agitated, we'll say...it can get a lot denser. Coronal holes move from the poles down to lower latitudes, and the Sun's face develops an astronomical case of acne. This usually occurs around the time of solar maximum.

Whoa. Waitaminit. What's “solar maximum”?

Our Sun has cycles that it goes through. Some are short and some are long. These cycles are related to its magnetic field and to sunspots. In fact, many variable star astronomers such as myself consider that the Sun is at least a borderline variable star because of this; some consider it outright variable. We'll leave that to a later discussion. For now, let's just look at those cycles and why they exist.

The Sun is a gigantic ball of plasma, a gas of ionized particules like protons and electrons. It spins on an axis. These two facts, when combined, create an electic current. An electric current, in turn, generates a magnetic field. This is why the Sun has a magnetic field, and it looks like a bar magnet – a “dipole.” (Remember elementary school when you put a piece of paper on a bar magnet and sprinkled iron filings on it? It made a cool bunch of lines that arced from one end of the magnet to the other, and then fanned out at the very ends. That's what I'm talking about.) The polar areas normally have “coronal holes,” because of the open-ended lines. The plasma flows out, away from the Sun, at high speeds (200-600km/s, 124-373 mi/s or 447,000-1,340,000 mph).

But since the Sun isn't solid like a bar magnet, the plasma doesn't all have to spin around the axis at the same speed – and it doesn't. The poles don't spin at the same rate as the equator, and the deeper layers don't spin at the same rate as the surface.

So let's think about those lines of iron filings again. Our bar magnet has gone and gotten itself all twisted up because it isn't solid, so the lines of iron filings get all twisted up, too. Now, scientists are still working on this, but the best we can figure out now is that sunspots are places where “snarls” form in the magnetic lines, and break through to the surface. (In the last couple of years we've learned how to look “deeper” into the Sun to see these snarls below the visible surface. Remember that. It'll come into play later on, when we start talking about the Sun as a variable star.) This means that sunspots have magnetic fields, sometimes very complicated. There are almost always at least two – one is a north magnetic pole, the other a south pole. (When there is just one, it is usually funny-shaped and one end will be North and the opposite end South. And sometimes there's a whole cluster, which gets really complicated.) And most all of the spots on the Sun will have the same N/S orientation.

It turns out that every 11 years, there is a peak in the number of sunspots, and a minimum in the number of sunspots. We aren't quite sure why, because we don't have all the theory worked out yet. But we've all heard of Solar Maximum and Solar Minimum, and that's what those terms mean. Solar Max is when we have the most spots, and Solar Min is when we have the least.

(To be continued.)

-Stephanie Osborn
http://www.stephanie-osborn.com