First Big Solar Flare of 2015

Active sunspot unleashes X-class solar flare, high-latitude aurora possible Friday

[...] What’s particularly interesting about this week’s eruptions is that the parent region is now near the center of the sun as we look at it, and it’s likely that a coronal mass ejection (CME) is now headed toward Earth thanks to the X2 flare.

Region 2297’s earlier eruptions occurred when it was in a less central position, so the launched CME would be, at worst, a side swipe for Earth’s magnetic field. The event on the afternoon of March 11, though, is much more likely to hit nearly head on.

High-latitude aurora watchers take note — the Space Weather Prediction Center is looking for minor magnetic storm activity on March 13. Plus, the sky will be relatively dark with the moon in its last quarter, so lunar light pollution is minimal. Get away from city lights for your best chance of seeing a glow.

The days following may be even more disturbed if Region 2297 has more in it.

The Ides of March? The Roman soothsayers made dire predictions for Caesar. For us, just a head’s up that some nice northern lights may be coming.

Follow the link for a larger photo. I like how they put the earth on there, for scale. The flare itself is much larger than our small world.

If you are science-minded and want to monitor the progress of this sunspot, you can do so here.
     

Recent X5-class solar flare

Sun unleashes huge solar flare; possible Earth-bound solar storm

Between 7 and 8 p.m.Tuesday night, the sun spit out a large, X5-class solar flare. NOAA’s Space Weather Prediction Center called it “one of the largest solar flares of the current solar cycle.”

X class flares are the strongest category of solar flares. According to NASA, they can trigger planet-wide radio blackouts and long-lasting radiation storms.

These flares are often complemented by phenomena known as coronal mass ejections (CME) which are essentially bursts of solar wind. If a CME is directed towards the Earth, a geomagnetic storm results that can interfere with the Earth’s magnetosphere.

NOAA said predictions for this particular flare/CME event “are still being refined.”

SpaceWeather.com wouldn’t draw any conclusions about where the CME might go.

“First-look data from STEREO-B are not sufficient to determine if the cloud is heading for Earth,” it said.

Its “best guess” was that CME probably won’t directly head for Earth, but rather produce a “glancing blow” on March 8 or 9. [...]

So we wait and see.

UPDATE 03-07-12 9:am

Full Halo CME heading straight for Earth on Thursday, strong effects forecast

(TheWeatherSpace.com) - A sunspot nearly the size of Jupiter; AR1429, has unleashed a powerful X5-Class eruption from the Sun and it could cause geological effects, according to one.

Even though it was not directly squared at our planet, model predictions have put Earth in the center of the blast zone, with 800 k/m + solar wind coming toward our geomagnetic fields on Thursday.

It will hit at 09:00 UT on Thursday, March 8th 2012. This means that it will hit during the United States aurora oval hours tonight when the oval extends down into the country. Will it spark bright auroras into the mid-latitudes?

TheWeatherSpace.com Senior Meteorologist Kevin Martin has studied space weather effects and geological triggers for many years post 1999. Martin has some chilling information to give.

"I'm a meteorologist, but I know patterns and numbers well and the last strong X-event that hit our planet on this scale "coincidentely" triggered the Japan quake and tsunami last year," said Martin. "Geomagnetic storms could very well be a trigger for these quakes as they react deep within the crust and mantle where magnetic rocks lie. There are things we just cannot ignore even if we cannot see them."

NOAA expects a major geomagnetic storm with this arrival. Already a Kp-Index of 6 (Strong) is in progress across the planet due to an X1-Class this past weekend. This X5-Class has yet to impact and is coming — straight for us at 800 km/sec.

Most scientists say there is no proven link between flares and earthquakes. But others argue that, there are lots of "coincidences".
     

Solar Storm Continues on with a New Blast

Biggest solar storm since 2005 underway, will peak Tuesday

Fast on the heels of a solar storm that delivered a glancing blow over the weekend — triggering bright auroras in Canada and Scandinavia — the sun released an even more energetic blast of radiation and charged plasma overnight that could disrupt GPS signals and the electrical grid Tuesday, especially at high latitudes, space weather experts warned Monday morning.

Already, the storm could be disrupting satellite communications as streams of radiation from the sun bounce across the Earth’s magnetic field, which extends above the surface into space.

“With the radiation storm in progress now, satellite operators could be experiencing trouble, and there are probably impacts as well to high frequency [radio] communications in polar regions,” said Doug Biesecker, a physicist at the Space Weather Prediction Center, part of the National Oceanic and Atmospheric Administration in Boulder, Colo.

Such radio blackouts can force airlines to reroute flights between North America and Europe or Asia.

Biesecker said any rocket launches scheduled for Monday probably would have to be scrubbed, although he said he was unaware of any planned launches.

The solar storm is the biggest since 2005, he added.

The storm will peak Tuesday when a speeding cloud of plasma and charged particles blasts past Earth, distorting the planet’s magnetic field with impacts possibly ranging as far south in latitude as Texas and Arizona.

“We expect moderate to potentially strong geomagnetic storming that can cause pipeline corrosion effects and power grid fluctuations,” Biesecker said.

Predictions from NASA scientists show the storm peaking about 9 a.m. Tuesday, although uncertainty in the prediction means the storm could peak up to seven hours earlier or later, said Michael Hesse of NASA’s Space Weather Laboratory, at the Goddard Space Flight Center in Greenbelt.

“It’s not going to be a catastrophe, but there could be noticeable geomagnetic current induced on the electrical grid,” Hesse said. [...]

It goes on to say that this plasma cloud is heading towards earth at high speed, the fastest one so far in this solar cycle. And speed matters, because the speed at which it hits the earths magnetic field will increase it's likely affects.

We shall see.



Planes expected to reroute following massive solar eruption

[...] According to NOAA, this is the strongest solar radiation storm since May 2005, and as a precaution, polar flights on Earth are expected to be re-routed within the next few hours, Kathy Sullivan, deputy administrator of NOAA, said today at the 92nd annual American Meteorological Society meeting in New Orleans, La.

[...]

"There is little doubt that the cloud is heading in the general direction of Earth," Spaceweather.com announced in an alert. "A preliminary inspection of SOHO/STEREO imagery suggests that the CME will deliver a strong glancing blow to Earth's magnetic field on Jan. 24-25 as it sails mostly north of our planet." [...]

A "strong glancing blow". See the whole thing for embedded links.

For updates from NOAA, check here:

NOAA / Space Weather Prediction Center

     

A very large and growing sunspot has appeared

Visualization of solar flare being ejected from the sun on November 3
courtesy NASA Solar Dynamics
Monster sunspot poses threat of significant solar storms

A major sunspot is presently emerging on the surface of the solar disk facing Earth. According to Jess Whittington at NOAA’s Space Weather Prediction Center (SWPC), the huge and still growing sunspot is the most active part of the sun since 2005.

The area is called Region 1339 and is being referred to as a “benevolent monster.” 8.3 times bigger than Earth, it generated a solar flare which shot out a burst of charged particles yesterday but - this time - was not aimed at Earth.

However, this extremely active area of the sun will be facing earth for about two weeks. At this time there is no way to predict whether new flares will generate significant solar storms aimed towards Earth and, if so, whether they could result in geomagnetic storms capable of dire consequences on “life as we know it”. [...]

Read the whole thing, for embedded links and more.
     

The Sounds of the Sun; What can they tell us?

Perhaps quite a bit:

Listening to the sun may improve space weather forecasts

Scientists at Stanford University find they can predict sunspots up to two days before they appear, which could help better foretell solar flares.

August 20, 2011|By Amina Khan, Los Angeles Times

Sunspots, those dark regions on the surface of the sun whose high magnetic activity has ripple effects for Earthlings, seem to emerge and fade without warning. But now, by listening to the sounds the sun makes, scientists have managed to predict when a sunspot will appear up to two days beforehand.

[...]

A team of Stanford University researchers tracked sound-generated activity at different points on the sun's surface and found that sound waves that would normally take an hour to cross from one point to the next traveled 12 to 16 seconds faster when a sun spot was emerging — a surprise, since the researchers expected to see perhaps only one second or so shaved off.

By monitoring sound waves about 37,000 miles below the solar surface, the physicists said, they can predict the emergence of a sunspot one to two days before it appears, depending on how large it is.

"It's very exciting that we can detect them before they become visible," said lead author Stathis Ilonidis, a graduate student studying solar physics at Stanford University. But he added that more data would be needed to show that their results hadn't turned up false positives.

The findings could prove useful to scientists looking to tie sunspots to the space weather events generated days later. Because areas of high magnetic activity are closely linked to dangerous solar activity — from flares to violent coronal mass ejections — being able to understand that magnetic activity may help predict oncoming solar storms and allow people to prepare for them, rather like putting up storm windows in response to a hurricane warning. [...]

Interesting. Thanks to new technologies, we are rapidly finding out a lot more about the sun than we ever knew before. But of course, the more we find out, the more questions we have, too.

I wonder how much we will find out by 2013, when the predicted solar maximum peaks? And it looks like there will be plenty of activity in the meantime too:

More Mammoth Solar Flares Expected From 'Old Faithful' Sunspot, Scientists Say

An active region of the sun that blasted out powerful solar storms four days in a row last week likely isn't done yet, scientists say.

Officially, the flare-spouting region is called sunspot 1283. But space weather experts have dubbed it "Old Faithful," after the famous geyser in the United States' Yellowstone National Park that goes off like clockwork. And the solar Old Faithful should erupt again before it dissipates, researchers said.

[...]

From Sept. 5-8, sunspot 1283 produced four big flares and three CMEs. Two of the flares were X-class events and two were M-class flares. (Strong solar flares are classified according to a three-tiered system: X-class are the most powerful, M-class are of medium strength and C-class are the weakest.)

While the rapid motion previously observed in sunspot 1283 seems to have died down a bit, Young said, the sunspot looks poised to erupt again sometime soon.

"There's a good probability that we're still going to see at least another M-class flare, possibly another X-class flare," Young told SPACE.com.

It's not uncommon for sunspots to pop off a number of powerful flares in quick succession the way 1283 has done, he added. That seems to be the natural order of things.

"When you see one big flare, your chances of seeing another one are pretty good," Young said. [...]

Well it looks like there will be lots more "chances" over the next couple of years.
     

Just what IS an "X-Class" Solar Flare?

This is a pretty good explanation:

Solar Flares: What Does It Take to Be X-Class?

Solar flares are giant explosions on the sun that send energy, light and high speed particles into space. These flares are often associated with solar magnetic storms known as coronal mass ejections (CMEs). The number of solar flares increases approximately every 11 years, and the sun is currently moving towards another solar maximum, likely in 2013. That means more flares will be coming, some small and some big enough to send their radiation all the way to Earth.

The biggest flares are known as "X-class flares" based on a classification system that divides solar flares according to their strength. The smallest ones are A-class (near background levels), followed by B, C, M and X. Similar to the Richter scale for earthquakes, each letter represents a 10-fold increase in energy output. So an X is ten times an M and 100 times a C. Within each letter class there is a finer scale from 1 to 9.

[...]

Although X is the last letter, there are flares more than 10 times the power of an X1, so X-class flares can go higher than 9. The most powerful flare measured with modern methods was in 2003, during the last solar maximum, and it was so powerful that it overloaded the sensors measuring it. The sensors cut out at X28.

The biggest X-class flares are by far the largest explosions in the solar system and are awesome to watch. Loops tens of times the size of Earth leap up off the sun's surface when the sun's magnetic fields cross over each other and reconnect. In the biggest events, this reconnection process can produce as much energy as a billion hydrogen bombs.

If they're directed at Earth, such flares and associated CMEs can create long lasting radiation storms that can harm satellites, communications systems, and even ground-based technologies and power grids. X-class flares on December 5 and December 6, 2006, for example, triggered a CME that interfered with GPS signals being sent to ground-based receivers. [...]

Follow the link for more info about all the different classes of flares, and a video too.


Also see: TheTchijevsky Index of Mass Human Excitability
     

Tottenham, and Riots and Geomagnetic Storms.

I've posted before about Geomagnetic storms/solar flares and riots. Coincidentally, the recent riots in Tottenham seem to coincide with this weekends solar weather:

BIG SUNSPOT GETS BIGGER; WEEKEND AURORAS; NIGHT-TIME SOLAR RADIO BURST

BIG SUNSPOT GETS BIGGER: Behemoth sunspot 1263 has almost doubled in size this weekend. A 28-hour movie from NASA's Solar Dynamics Observatory shows the spot developing a tail that has added some 50,000 km of length to the active region. This development may increase the likelihood of a strong flare. Images: #1, #2, #3

WEEKEND AURORAS: A widespread display of auroras erupted late Friday, Aug. 5th, when a double-CME hit Earth's magnetic field and sparked a G4-category geomagnetic storm. "It was the most impressive display I've seen in years," reports Lance Taylor of Edmonton, Alberta. "From 10:00 PM on Friday to 3:00 AM on Saturday, the sky was pulsing from horizon to horizon in every direction." He took this picture during the most intense phase of the storm:



The show was not restricted to Canada. Northern Lights spilled across the border into the United States as far south as Utah, Colorado, and Nebraska. (Note: The faint red lights photographed in Nebraska are typical of low-latitude auroras during major geomagnetic storms.) Observers in Europe as far south as England, Germany and Poland also witnessed a fine display. Browse the gallery for more examples. [...]

Follow the link to the original article, which has many embedded links, and for information about the night-time solar radio burst, which has not happened since 1958.
     

Will we end up wanting global warming?

Scientists predict rare 'hibernation' of sunspots

WASHINGTON (AFP) – For years, scientists have been predicting the Sun would by around 2012 move into solar maximum, a period of intense flares and sunspot activity, but lately a curious calm has suggested quite the opposite.

According to three studies released in the United States on Tuesday, experts believe the familiar sunspot cycle may be shutting down and heading toward a pattern of inactivity unseen since the 17th century.

The signs include a missing jet stream, fading spots, and slower activity near the poles, said experts from the National Solar Observatory and Air Force Research Laboratory.

"This is highly unusual and unexpected," said Frank Hill, associate director of the NSO's Solar Synoptic Network, as the findings of the three studies were presented at the annual meeting of the American Astronomical Society's Solar Physics Division in Las Cruces, New Mexico.

"But the fact that three completely different views of the Sun point in the same direction is a powerful indicator that the sunspot cycle may be going into hibernation."

Solar activity tends to rise and fall every 11 years or so. The solar maximum and solar minimum each mark about half the interval of the magnetic pole reversal on the Sun, which happens every 22 years.

Hill said the current cycle, number 24, "may be the last normal one for some time and the next one, cycle 25, may not happen for some time.

"This is important because the solar cycle causes space weather which affects modern technology and may contribute to climate change," he told reporters.

Experts are now probing whether this period of inactivity could be a second Maunder Minimum, which was a 70-year period when hardly any sunspots were observed between 1645-1715, a period known as the "Little Ice Age."

"If we are right, this could be the last solar maximum we'll see for a few decades. That would affect everything from space exploration to Earth's climate," said Hill. [...]

It sounds like guessing. And then it goes on to say that even if a "Little Ice Age" happens, we will still have to worry about Global Warming. Huh? Go figure.
     

Our recent Solar Weather continues

It really started getting interesting with the "Valentine's Day Flare":



Mega Solar Flare Fuels Earthly Disruption and Light Shows

A whopper of a solar flare that fired up earlier this week is wreaking havoc on some radio communications on Earth, and could spark exceptional auroras soon.

The class X solar flare – the most powerful kind of solar flare – spewed from the sun Monday (Feb. 14), unleashing a massive wave of charged particles speeding toward Earth. Now the flare has triggered a geomagnetic storm in our planet's magnetic field that interrupted radio communications in China and could disrupt satellites and power grids as well, AFP reported.

[...]

Monday's class X flare was the most powerful solar eruption in four years. It came on the heels of a few less powerful flares in the days before. [...]

The article has an embedded link, with video footage of the flare occurring.

I had read elsewhere that the number of sunspots had rapidly doubled in the days leading up to this. And particles from the CME will be continuing to hit the earth.

Catastrophe Looming? The Risks of Rising Solar Storm Activity

The sun let loose its most powerful eruption in more than four years Monday night (Feb. 14), disrupting radio communications in China and generating concern around the world. But it could have been a lot worse, experts say.

[...]

Solar flares are intense bursts of radiation that send waves of photons streaming toward Earth. The scale measuring their strength has three general categories – Class C, Class M and Class X – with Class X flares being the most powerful.

Monday's Valentine's Day solar flare registered a Class X2.2 on that scale.

Other storms, known as coronal mass ejections (CMEs), are large clouds of plasma and magnetic field that erupt from the sun's surface, sending lots of particles our way.

Both flares and CMEs have the same root cause — a disruption of the magnetic field in the sun's outer atmosphere. And both events can affect life here on Earth. Major flares, for example, can interfere with satellites, causing disruptions in GPS and high-frequency radio communications that can last from a few minutes to a few hours.

These impacts are felt almost immediately, since it only takes light about 8 minutes to travel from the sun to Earth.

"It's like the sun is a giant noise source," said Bob Rutledge, head of the forecast office at the National Oceanic and Atmospheric Administration's Space Weather Prediction Center. "It can disrupt anything that depends on a link between the ground and satellites."

But the most severe damage comes from powerful CMEs. The particles from these outbursts take longer to reach us — up to three days or so. But when they get here, their interaction with Earth's magnetic field can cause massive "geomagnetic storms," which have the potential to wreak long-lasting havoc on power and communications infrastructure around the globe.

[...]

But Earth has been walloped by monster solar storms before. One of the most powerful hit us in 1859, a blast that Rutledge estimates may have been 30 times more powerful than Monday's event, though it's tough to put hard numbers on such comparisons.

The 1859 storm shorted out telegraph wires, causing fires in North America and Europe, and spawned spectacular auroras — the light shows visible near Earth's poles — bright enough to read by, according to some accounts.

If the 1859 storm occured these days, it would likely have devastating impacts, since our electrical and communications infrastructures are so much more developed. A recent report by the U.S National Academy of Sciences found that such a severe storm could cause up to $2 trillion in initial damages by crippling communications on Earth and fueling chaos around the world.

It might take up to 10 years for authorities to re-assert control and get everyting fixed, the report concluded. For comparison, Hurricane Katrina likely inflicted somewhere between $80 billion and $125 billion in damage. [...]

I recently posted about a theory that solar flares affect people and stimulate political rebellions. The rapid increase in sunspots and the occurrence of these flares sure is a coincidence with the rebellions in the Middle East.

And I have posted previously about the hazards of solar storms to our technology (see links below). In the past few decades we have added thousands of communication satellites, and adopted widespread use of new technologies (like GPS) that are very sensitive to solar weather. A storm that previously we would have considered not so big or dangerous, might now present more concerns than it used to. Some precautions are being taken, by hardening the electrical grid, but has enough been done? Let's hope we don't have to find out the hard way.


Also see:

Our growing reliance on satellite technology, and it's vulnerability to solar flares. Why it matters.

Solar activity and it's disruption of GPS functions

Solar Flare: The "Carrington Event" of 1859
     

TheTchijevsky Index of Mass Human Excitability

Excitability, due to solar activity? I had previously posted about this last May. But with the recent increase in solar activity as we enter our Solar Maximum, I can't help but think of the Middle East. Compare what Tchijevsky said, and what is happening there now:

A. L. Tchijevsky’s Theory of Sunspot Activity and Human Activity

[...] That sunspot cycle activity increased and decreased in a cycle of approximately 11 years was established in the 1750s when astronomers began to make the first charts of the numbers of sunspots over time. During World War I, A. L. Tchijevsky, a Russian professor of Astronomy and Biological Physics who continued his studies at the war front, noticed that particularly severe battles regularly followed each solar flare during the sunspot peak period of 1916-17.

To test his hypothesis that sunspot cycle influenced human activity, Tchijevsky constructed an Index of Mass Human Excitability covering each year form 500 BC to 1922 AD. He then investigated the histories of 72 countries during that period, noting signs of human unrest such as wars, revolutions, riots, expeditions and migrations, plus the numbers of humans involved.

Tchijevsky found that fully 80% of the most significant events occurred during the 5 years of maximum sunspot activity. (Tchijevsky's merely noting that the 1917 Russian Revolution occurred during the height of the sunspot cycle earned him almost 30 years in Soviet prisons because his theory challenged Marxist dialectics.)

Tchijevsky divided the eleven year sunspot cycle into four social periods:

Period 1: (approximately 3 years, minimum sunspot activity). Peace, lack of unity among the masses, election of conservatives, autocratic, minority rule.

Period 2: (approx. 2 years, increasing sunspot activity). Increasing mass excitability, new leaders rise, new ideas and challenges to the elite.

Period 3: (Approximately 3 years, maximum sunspot activity). Maximum excitability, election of liberals or radicals, mass demonstrations, riots, revolutions, wars and resolution of most pressing demands.

Period 4: (Approximately 3 years, decreasing sunspot activity). Decrease in excitability, masses become apathetic, seek peace.

Tchijevsky did not believe solar disturbances caused discontent as much as they acted as detonators that set off the smoldering discontent of the masses--discontent often channeled into war by their rulers. Nor did he deny that even during minimum solar activity some people would rebel against intolerable conditions or that nations would seek advantage through war and conquest. Some have since noted that the number of sunspots during any period may not be as significant as whether there is a rapid increase in the numbers, triggering unexpected passions. [...]

In terms of solar activity, we are in a "period 3" now. Sunspot activity has been steadily increasing. Recently, we've had an X-class solar flare, with a coronal mass ejection. Does that count as a "sudden increase"?

Aurora borealis activity possible February 17-18, NOAA X-class solar flare

The National Oceanic and Atmospheric Administration (NOAA) reports that the most energetic solar flare in four years occurred on February 15, 2011. This X2 class solar flare also produced a coronal mass ejection which will increase the likelihood of aurora borealis activity, also known as the northern lights, on the night of February 17/18.

The solar flare originated from Sunspot 1158. X class solar flares are the most energetic solar flares. Flares also have sub classifications represented by numbers from 1 to 9, with the larger numbers representing more energetic flares. This X2 flare is energetic but near the lower end of X class flares.

This flare also produced a coronal mass ejection (CME) which is likely to strike Earth on February 18 (UTC date). During a CME the Sun spews out charged particles which can interact with Earth's magnetic field to cause aurora. The most likely night to see aurora activity (northern or southern lights) from this solar flare is the night of February 17/18, but it is also possible on the night of February 16/17.

This illustration shows how Earth's magnetosphere deflects, for the
most part, a magnetic cloud of plasma from a coronal mass ejection.

At high latitudes, NOAA predicts a 45% chance of aurora causing geomagnetic activity and a 25% chance of a minor geomagnetic storm. At mid latitudes the probabilities are 35% and 20%. [...]

It goes on to predict continuing activity from this sunspot.

I know that scientifically, there is insufficient data to prove any connection with political unrest in the Middle East. But still, I think it's "interesting" none the less.

But even if one considers that people are affected by solar activity, is the affect necessarily a negative one? Other research has shown that the peaks of solar activity have also been times of great advancement in human endevors, such as the arts and sciences:

Sunspots and Human Behavior

[...] In another historical study Suitbert Ertel writes in his article “Synchronous Bursts of Activity in Independent Cultures; Evidence for Extraterrestrial Connections” that evidence has been reported suggesting a link between historical oscillations of scientific creativity and solar cyclic variation. Eddy’s discovery of abnormal secular periods of solar inactivity (Maunders minimum type) offered the opportunity to put the present hypothesis to a crucial test. Using time series of flourish years of creators in science, literature, and painting (A.D. 600-1800) It was found as expected:

1. Cultural flourish curves show marked discontinuities (bursts) after the onset of secular solar excursions synchronously in Europe and China;

2. during periods of extended solar excursions, bursts of creativity in painting, literature, and science succeeded one another with lags of about 10-15 years;

3. The reported regularities of cultural output are prominent throughout with eminent creators. They decrease with ordinary professionals. The hypothesized extraterrestrial connection of human culture has thus been strengthened.

The evidence seems to show that during the maxima of sunspot activity human behavior is stimulated. [...]

Could it be that, solar maximums don't stimulate people in ways that make them agitated, but rather, they stimulate human creativity, causing people to strive for improvement. But in places where that creativity is stifled and repressed, where their creative energy has no creative outlet, no chance of improvement, that energy would then be directed to removing obstacles to the manifestation of that creativity and improvement? It's an interesting idea.
     

Solar storm not very dramatic

Most people in the USA won't get to see the aurora, either:

Where the best seats will be for northern lights after solar eruption

[...] The southernmost points in the United States where some form of northern lights may appear lie along the US-Canadian border – from northwestern Montana through northern Minnesota, Wisconsin, and Michigan's Upper Peninsula to the northern tip of Maine.

In the parlance of space-weather forecasters at the National Oceanic and Atmospheric Administration's Space Weather Prediction Center in Boulder, Colo., this is likely to be a G-1 (out of 5) solar storm – instead of a gee-whiz event for anyone south of Bemidji, Minn.

While that may be discouraging news for the aurora-starved, for commercial satellite owners and people who have to run electric transmission grids it's relatively good news. Geomagnetic storms can wreak havoc with electrically sensitive segments of today's high-tech infrastructure.

"There may be some temporary communications blackouts in the polar regions. If you're a GPS user needing centimeter accuracy, you'll feel this. If you're measuring currents on the power grid, you'll definitely see some changes in them. But only those intimately familiar with space weather are going to notice any effects," says Douglas Biesecker, a physicist at the Space Weather Prediction Center.

[...]

Several factors determine how intense a geomagnetic storm will be once a CME arrives, researchers say. They include the plasma's speed, its density (on average, perhaps one charged particle for every 0.06 cubic inches), whether Earth takes a direct hit from the densest region of the plasma, and the orientation of the plasma's magnetic field.

This ejection certainly had the speed at launch, Dr. Biesecker notes. Scientists clocked it at a hair less than 2.7 million miles an hour. So far, however, the plasma's speed near Earth has slowed to a more sedate 1.3 million miles an hour.

NOAA is testing a new space-weather forecast model that indicated Earth wouldn't take a direct hit from the densest part of the cloud, but instead would find itself enveloped roughly halfway between the densest region and the cloud's edge as the plasma sped past.

That may help account for the low ranking forecasters are giving this encounter.

Magnetic fields also matter.

Earth's field is not uniform around the planet, but somewhat flattened on the sunward half and stretched into a cometlike tail on the night half. As the plasma strikes Earth's magnetic field, it squashes and stretches Earth's field more than usual.

If the plasma's magnetic field is oriented in a way that offers the same average polarity to Earth as the planet's own field, it's like an express train passing a local station: The plasma's field races past Earth's magnetotail with little effect on the locals.

But if the polarities are opposite and attract, the plasma's field couples to the magnetotail and stretches it until it can stretch no farther. It snaps back toward Earth. The energy released in that snap accelerates charged particles already in the magnetotail, hurtling them on their collision course with Earth's upper atmosphere at the poles, where Earth's fields originate.

The more energy a snap releases, the stronger the storm and the lower the latitudes at which people can see auroral displays.

However, with today's orbiting sensors, the orientation of the plasma's field becomes clear only after it's passed and scientists have had a chance to study the data. [...]

The article has a video clip too. The storm is a class C, which is not very significant for us to worry about. A class M would be more serious, and a class X would be very serious.


Also see:

Our growing reliance on satellite technology, and it's vulnerability to solar flares. Why it matters.     

Solar Activity and Human Behavior: a link?

In response to an earlier post I did about Solar Flares and GPS disruption, someone commented about the affects that solar activity can have on human behavior.

Having read more about it since then, it seems that there are some interesting correlations. Here are some links I found on the subject:

Sunspots and Human Behavior
This article was published in the year 2000, just after the last Solar Maximum:

The recent Solar Maximum gives us a wonderful opportunity to observe the Sun in action. Borderland Sciences has been investigating the relationship of the Sun and human behaviour for many years, and we are quite confident that we can predict behaviours based on sunspot fluctuations over very short and long durations within the Solar Cycle of 11 years. Historically, research has been conducted to link the 11 year cycle of the sun to changes in human behavior and society. The most famous research had been done by professor A.L. Tchijevsky, a Russian scientist, who presented a paper to the American Meteorological Society at Philadelphia in the late 19th century. He prepared a study of the history of mass human movement compared to the solar cycle, beginning with the division of the Solar cycle into four parts: 1) Minimum sunspot activity; 2) increasing sunspot activity; 3) maximum sunspot activity; 4) Decreasing sunspot activity. He then divided up the agitation of mass human movements into five phases:

1) provoking influence of leaders upon masses

2) the “exciting” effect of emphasized ideas upon the masses

3) the velocity of incitability due to the presence of a single psychic center

4) the extensive areas covered by mass movements

5) Integration and individualization of the masses

By these comparisons he constructed an “Index of Mass Human Excitability” covering each year from 500 B.C. to 1922 A.D. He investigated the histories of 72 countries in that period, noting signs of human unrest such as wars, revolutions, riots, expeditions and migrations, plus the number of humans involved. Tchijevsky found that fully 80% of the most significant events occurred during the years of maximum sunspot activity. He maintained that the “exciting” period may be explained by an acute change in the nervous and psychic character of humanity, which takes place at sunspot maxima.

Tchijevsky discovered that the solar minimum is the lag period when repression is tolerated by the masses, as if they lacked the vital energy to make the needed changes. He found that during the sunspot maximum, the movement of humans is also at its peak. Tchijevsky’s study is the foundation of sunspot theory on human behavior, and as Harlan True Stetson, in his book Sunspots and Their Effects (available from BSRF), stated, “Until, however, someone can arrive at a more convincing excitability quotient for mass movements than professor Tchijevsky appears yet to have done, scientists will be reluctant to subscribe to all the conclusions which he sets forth.” Stetson did acknowledge that the mechanism by which ultraviolet radiation is absorbed was still a puzzle biologists had to solve. [...]

It's interesting, but I want more proof. Which leads to the next website, which goes into specific examples:

The Evidence: Historical Events During Sunspot Cycle Heights (1750-2000)

1905-08 German miners, Hottentots, Turks, Indians, Honduras, Russians revolt

1916-18 World War I, Irish and Indian revolts, Russian Revolution

1927-31 Mussolini and Hitler build power on economic unrest; revolts in Vienna, China; formation of Red Army; Spanish Republic formed; mass civil disobedience in India

1937-40 US steel strike, Spanish Civil War, Germany and Japan start World War II, mass civil disobedience in India

1947-51 Greek Civil War, First Israeli-Arab War, Indian-Pakistani riots, Red Army conquers China, Vietnam revolts, Korean War

1957-60 Israel invades Sinai, Hungarian uprising, Cuban revolution, civil rights movement in US, French-Algerian war, MauMau revolt, Iraq revolt, numerous African nations gain independence [...]

The website is maintained by Carol Moore, who gives many more examples like this, with graphs, which appear to support professor A.L. Tchijevsky's research and theory. She gives examples from 1770 up until 2009. Also on her site:

A. L. Tchijevsky’s Theory of Sunspot Activity and Human Activity

[...] Tchijevsky did not believe solar disturbances caused discontent as much as they acted as detonators that set off the smoldering discontent of the masses--discontent often channeled into war by their rulers. Nor did he deny that even during minimum solar activity some people would rebel against intolerable conditions or that nations would seek advantage through war and conquest. Some have since noted that the number of sunspots during any period may not be as significant as whether there is a rapid increase in the numbers, triggering unexpected passions. [...]

Ms. Moore has a lot more on her site. If the subject interests you, be sure to visit her webpage, she has a lot of source material for you to consider.

So the correlations make the theory more interesting, but what do we actually know, scientifically, about the affects of the sun's magnetic field on human beings? This site looks into that question:



Could Cycles of War or Peace Be Tied to Cycles of the Sun?

[...] Like weather patterns found on Earth, solar wind patterns can change rapidly. Luckily, our planet's magnetosphere quickly responds to the threat and absorbs the impact, wiggling and jiggling in the process. Geophysicists call this reaction a geomagnetic storm, but because of how it disrupts the Earth's magnetic field, it could also be called electromagnetic pollution.

These storms, although minute, affect brain waves and hormone levels, causing a number of different reactions, predominately in males. While a few women may also experience changes during these storms, they generally seem less affected by the Sun's behavior.

[...]

Reacting to changing hormone levels, some men may become increasingly irritable and aggressive, while others may instead become more creative. An increase in solar activity is found to increase psychotic episodes in individuals who already suffer from unstable psychological states. While we might relate such behavior to a full moon, in 1963, Dr. Robert Becker and his colleague, Dr. Freedman, demonstrated that solar changes also lead to a noticeable increase in psychotic activity.

Yet these reactions are not simply isolated to a few particularly sensitive or unlucky individuals. Evidence indicates that wars and international conflicts most often break out when sunspots are rapidly forming or rapidly decaying, as these are times when there are more intense geomagnetic storms. [...]

So do I believe it? I don't know. I can't verify all these claims. And I would like to see it investigated with a more solidly scientific method. But how does one "prove" that 80% concurrence of wars and solar storms is not a random coincidence? I'm not discounting it as a theory, but I think as a theory it has yet to be proven. For me it remains... interesting!
     

Solar activity and it's disruption of GPS functions

Sunspot activity is becoming stronger than it's been in many years. During the past several years, GPS technology has been dramatically increasing in use. It will now be facing interference on a scale not seen before. Are we ready for it?


Solar flares set to wreak havoc on GPS signals

The sun's activity isn't usually a hot topic around these parts, but when it threatens to derail satellite navigation services around the world, it must surely take center stage. UK researchers have corroborated Cornell's 2006 warning that our solar system's main life-giver is about to wake up and head toward a new solar maximum -- a period of elevated surface activity and radiation. It is precisely that radiation, which can be perceived in the form of solar flares, that worries people with respect to GPS signaling, as its effects on the Earth's ionosphere are likely to cause delays in data transmission from satellites to receivers and thereby result in triangulation errors. Still, it's more likely to be "troublesome than dangerous," but inaccuracies of around 10 meters and signal blackouts that could last for hours are being forecast in the absence of any intervening steps being taken. So yes, you now have another reason not to trust your GPS too much.

Follow the link to the orginal post on Engadget, which has embedded links.


GPS set for problems from the Sun

Researchers say the Sun is awakening after a period of low activity, which does not bode well for a world ever more dependent on satellite navigation.

The Sun's irregular activity can wreak havoc with the weak sat-nav signals we use.

The last time the Sun reached a peak in activity, satellite navigation was barely a consumer product.

But the Sun is on its way to another solar maximum, which could generate large and unpredictable sat-nav errors.

The satellite navigation concept is embodied currently by the US GPS system and Russia's Glonass network, with contenders to come in the form of Europe's Galileo constellation and China's Compass system.

It depends on what is - at its root - a simple triangulation calculation.

A fleet of satellites circling the Earth are constantly beaming a radio signal with two bits of exceptionally precise information: where exactly they are, and at exactly what time.

A sat-nav receiver on Earth - or on a ship or plane - is equipped with a fairly precise clock and the means to collect signals from the satellites that happen to be in its line of sight.

It then works out, based on how long it took those signals to arrive, how far it is from each of those satellites. Some simple geometry yields its position.

• 1. Satellites advertise their exact position, and the precise time at which they are sending it

• 2. The signal travels through the outer atmosphere, the ionosphere; its speed depends on how much the Sun's radiation and particle winds are affecting the ionosphere's composition

• 3. A receiver on Earth determines how long the signals took to arrive from a number of satellites, calculating the position from the time differences


But those signals are incredibly weak and, as researchers have only recently begun to learn, sensitive to the activity on the Sun.

Solar flares - vast exhalations of magnetic energy from the Sun's surface - spray out radiation across the electromagnetic spectrum, from low-energy radio waves through to high-energy gamma-rays, along with bursts of high-energy particles toward the Earth.

The radiation or waves that come from the Sun can make sat-nav receivers unable to pick out the weak signal from satellites from the solar flare's aftermath.

There is little that current technology can do to mitigate this problem, with the exception of complex directional antennas used in military applications.

Sat-nav receivers will be blinded for tens of minutes, probably a few times a year at the solar maximum.

Charged up

A further complication comes from the nature of the outermost layer of the Earth's atmosphere, the ionosphere.

That is composed in part of particles that have ionised, or been ripped apart by radiation from the Sun, with the composition dependent on how much radiation is coming from the Sun at a given time. [...]

Read the whole thing for further explanation and details.


Another detailed article from the BBC is here:

Sat-nav devices face big errors as solar activity rises

It explains the problem well, and even offers some suggestions for how it might be coped with in some instances.
     

Sunspots and Solar Minimums: what they mean

How are the lack of sunspots related to a Solar Minimum, and how does that affect temperatures here on earth? And what about our current solar cycle?


I had read a while back, in an article that I can't find now, that the lack of sunspots doesn't cause the sun to be significantly cooler, and does not cool the earth down significantly either. The cooler temperatures happen indirectly. If I understand it correctly:

Sunspots are magnetic storms on the sun's surface. They cause solar winds, that in turn cause ions in the earth's upper atmosphere to become charged, churning the air which affects the wind currents on the earth.

The earth's oceans absorb much of the suns heat, warming the air above, and the earth's westerly winds blow that warmer air over the oceans westward onto land masses, raising the temperature there.

When sun spot activity is very low or non-existent, the ions in the upper atmosphere are less charged, there is less air movement, and the westerly winds die down, leaving more of the warmer air over the oceans. As a result, there is a significant drop of temperatures over the land masses.

Fascinating stuff. I couldn't find that article, but while searching for it I came across the following articles about our current solar cycle. As the new solar cycle continues to be weak, lacking significant sunspot activity, it seems we are in a solar minimum.

There has even been speculation by some that we are entering a "mini-ice age" like the historical "Maunder Minimum":


Wikipedia: Maunder Minimum

The Maunder Minimum is the name used for the period roughly spanning 1645 to 1715 by John A. Eddy in a landmark 1976 paper published in Science titled "The Maunder Minimum",[1] when sunspots became exceedingly rare, as noted by solar observers of the time. Astronomers before Eddy had also named the period after the solar astronomer Edward W. Maunder (1851–1928) who studied how sunspot latitudes changed with time.[2] The periods he examined included the second half of the 17th century. Edward Maunder published two papers in 1890 and 1894, and he cited earlier papers written by Gustav Spörer. The Maunder Minimum's duration was derived from Spörer's work. Like the Dalton Minimum and Spörer Minimum, the Maunder Minimum coincided with a period of lower-than-average global temperatures.

During one 30-year period within the Maunder Minimum, astronomers observed only about 50 sunspots, as opposed to a more typical 40,000–50,000 spots in modern times. [...]

As Wikipedia points out, there have also been smaller solar minimums, like the Dalton and Spörer minimums. We may be experiencing a minimum, but it's size may be unpredictable. I would say comparing it to the "Maunder Minimum" could be premature. Yet some astronomers are taking it even further than being just a minimum:

ARE SUNSPOTS DISAPPEARING?

[...] According to Bill Livingston and Matt Penn of the National Solar Observatory in Tucson, Arizona, sunspot magnetic fields are waning. The two respected solar astronomers have been measuring solar magnetism since 1992. Their technique is based on Zeeman splitting of infrared spectral lines emitted by iron atoms in the vicinity of sunspots. Extrapolating their data into the future suggests that sunspots could completely disappear within decades. That would be a bummer for Spaceweather.com.

Don't count out sunspots just yet, however. While the data of Livingston and Penn are widely thought to be correct, far-reaching extrapolations may be premature. This type of measurement is relatively new, and the data reaches back less than 17 years. [...]

Yes, 17 years is nothing in the lifespan of the sun. Not enough data to make long term predictions. In fact, for all we know about the sun now, it's amazing how much we can't predict, as this NASA article shows:

Deep Solar Minimum

April 1, 2009: The sunspot cycle is behaving a little like the stock market. Just when you think it has hit bottom, it goes even lower.

2008 was a bear. There were no sunspots observed on 266 of the year's 366 days (73%). To find a year with more blank suns, you have to go all the way back to 1913, which had 311 spotless days: plot. Prompted by these numbers, some observers suggested that the solar cycle had hit bottom in 2008.

Maybe not. Sunspot counts for 2009 have dropped even lower. As of March 31st, there were no sunspots on 78 of the year's 90 days (87%).

It adds up to one inescapable conclusion: "We're experiencing a very deep solar minimum," says solar physicist Dean Pesnell of the Goddard Space Flight Center.

"This is the quietest sun we've seen in almost a century," agrees sunspot expert David Hathaway of the Marshall Space Flight Center.

[...]

Quiet suns come along every 11 years or so. It's a natural part of the sunspot cycle, discovered by German astronomer Heinrich Schwabe in the mid-1800s. Sunspots are planet-sized islands of magnetism on the surface of the sun; they are sources of solar flares, coronal mass ejections and intense UV radiation. Plotting sunspot counts, Schwabe saw that peaks of solar activity were always followed by valleys of relative calm—a clockwork pattern that has held true for more than 200 years: plot [see article for link].

The current solar minimum is part of that pattern. In fact, it's right on time. "We're due for a bit of quiet—and here it is," says Pesnell.

But is it supposed to be this quiet?

[...]

All these lows have sparked a debate about whether the ongoing minimum is "weird", "extreme" or just an overdue "market correction" following a string of unusually intense solar maxima.

"Since the Space Age began in the 1950s, solar activity has been generally high," notes Hathaway. "Five of the ten most intense solar cycles on record have occurred in the last 50 years. We're just not used to this kind of deep calm."

Deep calm was fairly common a hundred years ago. The solar minima of 1901 and 1913, for instance, were even longer than the one we're experiencing now. To match those minima in terms of depth and longevity, the current minimum will have to last at least another year.

[...]

Modern technology cannot, however, predict what comes next. Competing models by dozens of top solar physicists disagree, sometimes sharply, on when this solar minimum will end and how big the next solar maximum will be. Pesnell has surveyed the scientific literature and prepared a "piano plot" showing the range of predictions. The great uncertainty stems from one simple fact: No one fully understands the underlying physics of the sunspot cycle.

Pesnell believes sunspot counts will pick up again soon, "possibly by the end of the year," to be followed by a solar maximum of below-average intensity in 2012 or 2013. [...]

The article has a lot of particulars, about the new "lows" the minimum is causing, in the rate of solar wind pressure, irradiance, and solar radio emissions. Read the whole thing for the details.

The article began with a comparison to the stock market, and ends with one. The sun and the stock market may well have something in common; no one can know and completely understand ALL the forces at work behind the scenes that drive them, and therefore, no one can completely predict their behavior. But plenty of people still take "educated guesses" about both.

You can read more about what Livingston and Penn say about sunspots during a solar minimum in this PDF document online:

Are Sunspots Different During This Solar Minimum?

They talk in more detail about what they are measuring, how they are measuring it, and what it might mean.


Related Links:

Where have all the sunspots gone, and why?

Our climate, the weather, our grid and the Sun

Solar Flare: The "Carrington Event" of 1859
     

Solar Flare: The "Carrington Event" of 1859

In a post I did a few days ago, about sunspot activity, the famous solar storm of 1859, often referred to as the "Carrington Event", was frequently mentioned. I've been reading up on that, and here is some of the information I found:

A Super Solar Flare

At 11:18 AM on the cloudless morning of Thursday, September 1, 1859, 33-year-old Richard Carrington—widely acknowledged to be one of England's foremost solar astronomers—was in his well-appointed private observatory. Just as usual on every sunny day, his telescope was projecting an 11-inch-wide image of the sun on a screen, and Carrington skillfully drew the sunspots he saw.

On that morning, he was capturing the likeness of an enormous group of sunspots. Suddenly, before his eyes, two brilliant beads of blinding white light appeared over the sunspots, intensified rapidly, and became kidney-shaped. Realizing that he was witnessing something unprecedented and "being somewhat flurried by the surprise," Carrington later wrote, "I hastily ran to call someone to witness the exhibition with me. On returning within 60 seconds, I was mortified to find that it was already much changed and enfeebled." He and his witness watched the white spots contract to mere pinpoints and disappear.

It was 11:23 AM. Only five minutes had passed.

Just before dawn the next day, skies all over planet Earth erupted in red, green, and purple auroras so brilliant that newspapers could be read as easily as in daylight. Indeed, stunning auroras pulsated even at near tropical latitudes over Cuba, the Bahamas, Jamaica, El Salvador, and Hawaii.

Even more disconcerting, telegraph systems worldwide went haywire. Spark discharges shocked telegraph operators and set the telegraph paper on fire. Even when telegraphers disconnected the batteries powering the lines, aurora-induced electric currents in the wires still allowed messages to be transmitted.

"What Carrington saw was a white-light solar flare—a magnetic explosion on the sun," explains David Hathaway, solar physics team lead at NASA's Marshall Space Flight Center in Huntsville, Alabama.

[...]

The explosion produced not only a surge of visible light but also a mammoth cloud of charged particles and detached magnetic loops—a "CME"—and hurled that cloud directly toward Earth. The next morning when the CME arrived, it crashed into Earth's magnetic field, causing the global bubble of magnetism that surrounds our planet to shake and quiver. Researchers call this a "geomagnetic storm." Rapidly moving fields induced enormous electric currents that surged through telegraph lines and disrupted communications.

"More than 35 years ago, I began drawing the attention of the space physics community to the 1859 flare and its impact on telecommunications," says Louis J. Lanzerotti, retired Distinguished Member of Technical Staff at Bell Laboratories and current editor of the journal Space Weather. He became aware of the effects of solar geomagnetic storms on terrestrial communications when a huge solar flare on August 4, 1972, knocked out long-distance telephone communication across Illinois. That event, in fact, caused AT&T to redesign its power system for transatlantic cables. A similar flare on March 13, 1989, provoked geomagnetic storms that disrupted electric power transmission from the Hydro Québec generating station in Canada, blacking out most of the province and plunging 6 million people into darkness for 9 hours; aurora-induced power surges even melted power transformers in New Jersey. In December 2005, X-rays from another solar storm disrupted satellite-to-ground communications and Global Positioning System (GPS) navigation signals for about 10 minutes. That may not sound like much, but as Lanzerotti noted, "I would not have wanted to be on a commercial airplane being guided in for a landing by GPS or on a ship being docked by GPS during that 10 minutes." [...]

From what I've read, Canada and many of the Scandinavian countries have experienced the most electrical damage from solar storms, because of their proximity to the North pole (these effects can emanate from the South pole too, I believe, but there are fewer people and electrical grids nearby to be affected). The affects of a larger solar storm could be farther-reaching.

The Biggest Solar Storm in History

It was the 2 September 1859. The clipper ship Southern Cross was off Chile when, at 1:30am, it sailed into a living hell. Hailstones from above and waves from all around whipped the deck. When the wind-lashed ocean spray fell away to leeward, the men noticed they were sailing in an ocean of blood. The colour was reflected from the sky, which, they could see – even through the clouds – was wreathed in an all-encompassing red glow.

The sailors recognised the lights as the southern aurora that usually graced the skies near the Antarctic Circle, just as their northern counterparts cling to the Arctic. To see them from this far north was highly unusual. As the gale subsided, they witnessed an even more astonishing display. Fiery lights loomed against the horizon as if some terrible conflagration had engulfed the Earth. Vivid bolts flew across the now clear sky in spiral streaks and exploded in silent brilliance, as if the very souls of all humanity were fleeing whatever cataclysm had befallen the planet.

Upon their arrival at San Francisco, the ship’s company discovered that theirs was not an isolated experience. Two thirds of the Earth’s skies had been similarly smothered. Also, there was a sinister side to the aurorae.

The beguiling lights had disabled the telegraph system, wiping out communications across the world. For days, nature refused to allow these arteries of information to flow freely. It was as if today’s Internet had suddenly, inexplicably shut down. Worse still, the aurora also threatened life and limb.

In Philadelphia, a telegrapher was stunned by a severe shock. In some offices the equipment burst into flames. In Bergen, Norway, the operators had to scramble to disconnect the apparatus, risking electrocution. On top of this, compasses spun uselessly under the grip of the aurora, disrupting global navigation. [...]

It's obvious the flare caused considerable trouble back in 1859. What impact would such a solar storm have on our modern world, if it occurred today?


Blogger Neil Craig has some excerpts from Michael Brooks' report in NewScientist Magazine on what could happen if a solar storm the size of the "Carrington Event" were to happen today:

SEPTEMBER 1859 - CARRINGTON EVENT THE WORLDWIDE CATASTROPHE YOU NEVER HEARD OF

[...] it is clear that a repeat of the Carrington event could produce a catastrophe the likes of which the world has never seen. "It's just the opposite of how we usually think of natural disasters," says John Kappenman, a power industry analyst with the Metatech Corporation of Goleta, California, and an advisor to the NAS committee that produced the report. "Usually the less developed regions of the world are most vulnerable, not the highly sophisticated technological regions."

According to the NAS report, a severe space weather event in the US could induce ground currents that would knock out 300 key transformers within about 90 seconds, cutting off the power for more than 130 million people (see map). From that moment, the clock is ticking for America.

First to go - immediately for some people - is drinkable water. Anyone living in a high-rise apartment, where water has to be pumped to reach them, would be cut off straight away. For the rest, drinking water will still come through the taps for maybe half a day. With no electricity to pump water from reservoirs, there is no more after that.

There is simply no electrically powered transport: no trains, underground or overground. Our just-in-time culture for delivery networks may represent the pinnacle of efficiency, but it means that supermarket shelves would empty very quickly - delivery trucks could only keep running until their tanks ran out of fuel, and there is no electricity to pump any more from the underground tanks at filling stations.

Back-up generators would run at pivotal sites - but only until their fuel ran out. For hospitals, that would mean about 72 hours of running a bare-bones, essential care only, service. After that, no more modern healthcare.

The truly shocking finding is that this whole situation would not improve for months, maybe years: melted transformer hubs cannot be repaired, only replaced. "From the surveys I've done, you might have a few spare transformers around, but installing a new one takes a well-trained crew a week or more," says Kappenman. "A major electrical utility might have one suitably trained crew, maybe two."

Within a month, then, the handful of spare transformers would be used up. The rest will have to be built to order, something that can take up to 12 months.

Even when some systems are capable of receiving power again, there is no guarantee there will be any to deliver. Almost all natural gas and fuel pipelines require electricity to operate. Coal-fired power stations usually keep reserves to last 30 days, but with no transport systems running to bring more fuel, there will be no electricity in the second month.

...With no power for heating, cooling or refrigeration systems, people could begin to die within days. There is immediate danger for those who rely on medication. Lose power to New Jersey, for instance, and you have lost a major centre of production of pharmaceuticals for the entire US. Perishable medications such as insulin will soon be in short supply. "In the US alone there are a million people with diabetes," Kappenman says. "Shut down production, distribution and storage and you put all those lives at risk in very short order."

Help is not coming any time soon, either....
"I don't think the NAS report is scaremongering," says Mike Hapgood, who chairs the European Space Agency's space weather team. Green agrees. "Scientists are conservative by nature and this group is really thoughtful," he says. "This is a fair and balanced report."... [...]

The article goes on about some of the things we might do to lessen the threat, but also acknowledges the difficulties of convincing people of the threat, and taking the necessary precautions.

I have posted before about how our dependency on electricity and computer chips increases our vulnerability to EMP (Electro-Magnetic Pulse) weapons:

EMP Vulnerability: Could Advanced Electronics be the Achilles' Heel of our Western Civilization?

While the emphasis on that post was the danger posed from EMP weapons, the effects of large solar storm/flares share some similarities with EMP events. Both involve fluctuations in the Earth's magnetic field, that are damaging to electrical systems. And the safeguards needed to protect our electrical infrastructure from said fluctuations, be they from natural or man-made sources, are largely the same. Yet it's hard to convince people of the need to protect against something that has never happened in their own experience, or in the case of the Carrington Event, within living people's memory.

Even with the solar storm of 1859, there were no advanced electronics. The U.S. electric power industry didn't even exist yet (it only began in 1882). A comparison with today is difficult.

Today's advanced electronics, like computer microchips, are very vulnerable to magnetic field fluctuations, but we have only had them in wide use in recent decades. People aren't likely to think of the consequences of them failing en-mass, until they do.

Some people argue that storms like the Carrington Event only occur every 500 years or so, so why worry? But the data and arguments on that assertion are disputed, it's by no means a certainty. Also, a storm or flare of lesser strength still might do a lot of damage nowadays, given the delicate nature of our advanced electronics. Oddly enough, there could be a blessing in that, if it makes people aware of the danger, and more likely to protect against a larger event. Hopefully we won't have to learn hard way, by the worst scenario.

Since 1859, several solar storms about half the strength of the Carrington Event have been observed; but none of those observed flares were moving in the direction of Earth. It may be just a matter of time before one does. Scientists are watching the sun closely. We've learned more about the sun in the past decade, than we have in the last 100 years, but we still can't predict solar flares yet. Hopefully our ability to do that will improve over time. And hopefully, the next big storm we do experience won't be as big as the Carrington Event.


Related Links:

Our climate, the weather, our grid and the Sun

Could another Carrington Event destroy our economy?

Solar cycle 24: solar flares & social collapse or ‘crushing cold temperatures and global famine'?
     

Our climate, the weather, our grid and the Sun

Sun entering weakest cycle since 1928
NOAA releases new predictions for solar cycle

The sun has entered its weakest cycle of magnetic activity since 1928, meaning fewer solar flares and coronal mass ejections, scientists predicted in a May 8 teleconference. A panel of solar scientists assembled by the National Oceanic and Atmospheric Administration’s Space Weather Prediction Center reports that the cycle, which scientists believe began in December 2008, will peak in May 2013.

Storms of solar magnetic activity cause flares and ejections that can spit X-rays, UV light and billions of tons of charged particles into space, and toward Earth. These outbursts can make Earth’s upper atmosphere expand, potentially knocking out electrical grids and disrupting satellite communications — and can harm spacewalking astronauts.

“It’s fair to say we probably won’t see a whole lot of solar storms from this cycle,” Douglas Biesecker of NOAA’s Space Weather Prediction Center in Boulder, Colo., said at the teleconference. “But a weaker cycle won’t lessen the intensity of the storms, just the number of them.” [...]

I had done an earlier post about the current solar minimum being extended, almost two years longer than it's expected cycle. The decrease in sunspot activity seems to coincide with colder than normal temperatures globally.

I can only wonder, if solar activity can slow down to the point where it extends beyond it's predicted cycle, might it not also move in the other direction too? Sort of like a pendulum, that swings in one direction, then back again an equal distance in the opposite direction? If we see below normal sunspot activity now, will we see higher than normal activity later?

The first article mentioned above made reference to solar storms. The earth has experienced many solar storms in it's past, but not any really big ones since humankind began using electricity on a large scale. The last great solar storm happened in 1859:

Relatively mild sunspot cycle predicted, but even 1 solar storm can damage Earth

WASHINGTON — When the sun sneezes it’s Earth that gets sick.

It’s time for the sun to move into a busier period for sunspots, and while forecasters expect a relatively mild outbreak by historical standards, one major solar storm can cause havoc with satellites and electrical systems here.

Like hurricanes, a weak cycle refers to the number of storms, but it only takes one powerful storm to create chaos, said scientist Doug Biesecker of the National Oceanic and Atmospheric Administration’s space weather prediction center.

A report by the National Academy of Sciences found that if a storm as severe as one in 1859 occurred today, it could cause $1 trillion to $2 trillion in damage the first year and take four to 10 years to recover.

The 1859 storm shorted out telegraph wires, causing fires in North America and Europe, sent readings of Earth’s magnetic field soaring, and produced northern lights so bright that people read newspapers by their light.

Today there’s a lot more than telegraph lines at stake. Vulnerable electrical grids circle the globe, satellites now vital for all forms of communications can be severely disrupted along with the global positioning system. Indeed, the panel warned that a strong blast of solar wind can threaten national security, transportation, financial services and other essential functions.

The solar prediction center works closely with industry and government agencies to make sure they are prepared with changes in activity and prepared to respond when damage occurs, Biesecker said in a briefing.

While the most extreme events seem unlikely this time, there will probably be smaller scale disruptions to electrical service, airline flights, GPS signals and television, radio and cell phones. [...]

Read the whole thing. It says that sunspot measuring has been going on since the 1750's. When it comes to climate and weather, most of us only think in terms of what we've experienced directly, in our lifetime. But there is so much more historically. It's too easy to get hysterical about climate change, without that historical understanding of past changes and a scientific understanding of all the factors affecting our climate and weather, the sun being the most powerful.

People fear what they don't understand. If we understand the dynamics of climate change on earth, we can adapt to it when necessary and work with the ebb and flow of nature, instead of uselessly struggling to control it. We simply cannot control the sun.


Another article from NASA that mentions the 1859 solar storm:

New Solar Cycle Prediction

[...] It is tempting to describe such a cycle as "weak" or "mild," but that could give the wrong impression.

"Even a below-average cycle is capable of producing severe space weather," points out Biesecker. "The great geomagnetic storm of 1859, for instance, occurred during a solar cycle of about the same size we’re predicting for 2013."

The 1859 storm--known as the "Carrington Event" after astronomer Richard Carrington who witnessed the instigating solar flare--electrified transmission cables, set fires in telegraph offices, and produced Northern Lights so bright that people could read newspapers by their red and green glow. A recent report by the National Academy of Sciences found that if a similar storm occurred today, it could cause $1 to 2 trillion in damages to society's high-tech infrastructure and require four to ten years for complete recovery. For comparison, Hurricane Katrina caused "only" $80 to 125 billion in damage. [...]

I'm not saying it's going to happen again soon. But it is likely to happen again sometime. And those who know the history of the sun and it's potential behaviors won't be taken completely by surprise by it. And hopefully, will be prepared for it. Katrina was also predicted, and would have been less damaging if more people had paid attention and acted accordingly.
     

Where have all the sunspots gone, and why?

For the past 3 years, sunspot activity has been greatly reduced. I came across this article recently, that offers an explanation as to why this is so:

Mystery of the Missing Sunspots, Solved?

June 17, 2009: The sun is in the pits of a century-class solar minimum, and sunspots have been puzzlingly scarce for more than two years. Now, for the first time, solar physicists might understand why.

At an American Astronomical Society press conference today in Boulder, Colorado, researchers announced that a jet stream deep inside the sun is migrating slower than usual through the star's interior, giving rise to the current lack of sunspots.

[...]

Howe and Hill found that the stream associated with the next solar cycle has moved sluggishly, taking three years to cover a 10 degree range in latitude compared to only two years for the previous solar cycle.

The jet stream is now, finally, reaching the critical latitude, heralding a return of solar activity in the months and years ahead.

"It is exciting to see", says Hill, "that just as this sluggish stream reaches the usual active latitude of 22 degrees, a year late, we finally begin to see new groups of sunspots emerging."

The current solar minimum has been so long and deep, it prompted some scientists to speculate that the sun might enter a long period with no sunspot activity at all, akin to the Maunder Minimum of the 17th century. This new result dispells those concerns. The sun's internal magnetic dynamo is still operating, and the sunspot cycle is not "broken."

Because it flows beneath the surface of the sun, the jet stream is not directly visible. Hill and Howe tracked its hidden motions via helioseismology. [...]

It shows how the current cycle has dragged on for a year longer than usual, but also goes on to explain why that is about to change soon. It also explains more about helioseismology, and NASA's upcoming launch of the Solar Dynamics Observatory (SDO), which will provide us with more information about the sun. Interesting stuff.
     

Global Temperatures, Sun Spots & Cosmic Rays

Too much of the hysteria surrounding global warming has involved cooking the figures by leaving out data. This article from Meridian Magazine show us many of the ways this is done:

All in a Good Cause

[...] If you pay close attention, you'll find that Global Warming alarmists are not actually saying "Global Warming" lately. No, nowadays it's "Climate Change." Do you know why?

Because for the past three years, global temperatures have been falling.

Oops.

The thing is, we've had twenty years since the Alarmists first raised the banner of Global Warming. They told us that "If This Goes On" by 2010 or 2020, sea levels will be rising so high that coastal cities will be flooded, famines will cover the earth, and ...

Oh, you know the list. They're still making the same predictions — they just move the dates farther back.

It's like those millennarian religious cults in the 1800s. Religious leaders would arise who would predict the Second Coming of Christ in 1838. When Christ didn't oblige them by showing up, they went back to their visions or scripture calculations or whatever they claimed and report that they miscalculated, now it was going to be 1843. Or whatever.

Here's the raw truth:

All the computer models are wrong. They have not only failed to predict the future, they can't even predict that past.

That is, when you run their software with the data from, say, the 1970s or 1980s, and project what should happen in the 1990s or 2000s, they project results that have absolutely nothing to do with the known climate data for those decades.

In other words, the models don't work. The only way to make them "work" is to take the known results and then fiddle with the software until it finally produces them. That's not how honest science is done.

Why are so many scientists so wrong? [...]

Bold emphasis mine. Read the whole thing, there is so much more. Real science needs to be talked about, examined and discussed rationally, not religiously.


So how about some REAL and HONEST science? See what these two Danish researchers discovered:

The sun moves climate change

[...] For more than a decade, Henrik Svensmark of the Danish National Space Center has been pursuing an explanation for why Earth cools and warms. His findings -- published in October in the Proceedings of the Royal Society -- the mathematical, physical sciences and engineering journal of the Royal Society of London -- are now in, and they don't point to us. The sun and the stars could explain most if not all of the warming this century, and he has laboratory results to demonstrate it. Dr. Svensmark's study had its origins in 1996, when he and a colleague presented findings at a scientific conference indicating that changes in the sun's magnetic field -- quite apart from greenhouse gases -- could be related to the recent rise in global temperatures.

[...]

Svensmark and his colleague had arrived at their theory after examining data that showed a surprisingly strong correlation between cosmic rays --highspeed atomic particles originating in exploded stars in the Milky Way -- and low-altitude clouds. Earth's cloud cover increased when the intensity of cosmic rays grew and decreased when the intensity declined.

Low-altitude clouds are significant because they especially shield the Earth from the sun to keep us cool. Low cloud cover can vary by 2% in five years, affecting the Earth's surface by as much as 1.2 watts per square metre during that same period. "That figure can be compared with about 1.4 watts per square metre estimated by the Intergovernmental Panel on Climate Change for the greenhouse effect of all the increase in carbon dioxide in the air since the Industrial Revolution," Dr. Svensmark explained.

The Danish scientists put together several well-established scientific phenomena to arrive at their novel 1996 theory. The sun's magnetic field deflects some of the cosmic rays that penetrate the Earth's atmosphere, and in so doing it also limits the immense amounts of ions and free electrons that the cosmic rays produce. But something had changed in the 20th century: The sun's magnetic field more than doubled in strength, deflecting an extraordinary number of rays. Could the diminution of cosmic rays this century have limited the formation of clouds, making the Earth warmer? [...]

Read on to see how these men proceeded to go about proving this theory. And why the global warming alarmists don't want you to hear about it.


Here is more on the cosmic ray connection in this article by Richard Black, for the BBC News:

Sun and global warming: A cosmic connection?

[...] Over the course of the Earth's history, the main factor driving changes in its climate has been that the amount of energy from the Sun varies, either because of wobbles in the Earth's orbit or because the Sun's power output changes.

Most noticeably, it changes with the 11-year solar cycle, first identified in the mid-1800s by astronomers who noticed periodic variations in the number of sunspots.

If it varied enough, it could change the Earth's surface temperature markedly. So is it?

[...]

Henrik Svensmark and his collaborators at the Danish National Space Center (DNSC) believe the missing link between small solar variations and large temperature changes on Earth are cosmic rays.

"I think the Sun is the major driver of climate change," he says, "and the reason I'm saying that is that if you look at historical temperature data and then solar activity and cosmic ray activity, it actually fits very beautifully.

"If CO2 is a very important climate driver then you would expect to see its effect on all timescales; and for example when you look at the last 500 million years, or the last 10,000 years, the correlation between changes in CO2 and climate are very poor."

When hugely energetic galactic cosmic rays - actually particles - crash into the top of the atmosphere, they set in train a sequence of events which leads to the production of ions in the lower atmosphere.

The theory is that this encourages the growth of tiny aerosol particles around which water vapour can condense, eventually aiding the formation of clouds.

And the link to the Sun? It is because cosmic rays are partially deflected by the solar wind, the stream of charged particles rushing away from the Sun, and the magnetic field it carries. A weaker solar wind means more cosmic rays penetrating the atmosphere, hence more clouds and a cooler Earth. [...]

Read more to see what calm, rational, logical and provable science looks like. The cosmic ray theory is not new, and it has been studied continuously and expanced on since the 1950's. Many tenets of this theory are now provable through lab testing, and the historical data collected fits together to support it, in the complete and WHOLE picture. It's demonstratably correct, and makes more sense than incomplete data manipulated with software.