Watch this Solar Prominence Blast Off the Surface of the Sun

“I may not get a lot done today with the Sun putting on this sort of show”, announced amateur astrophotographer Paul Stewart from his upside down observatory in New Zealand yesterday. No kidding Paul, I can’t imagine anything else that you should be doing with your day other than recording this amazing animation of a massive prominence blasting off the surface of the Sun.

The animation you’re seeing attached to this article was captured by Paul on January 10th, 2013 and consists of 28 separate images of the Sun. But each of these images is actually a composite of about 1000 frames of video; only the best 30% of the frames were kept, and the rest were discarded. Paul stacked up each individual frame using AutoStakkert with Registax, and then manually lined them up in Photoshop. Finally, the whole thing was animated in Virtualdub.

Wondering about the gear Paul used? He was equipped with a Lunt Solar Systems 80mm H-Alpha Pressure Tuned Telescope (that’s it over on the right), using a DMK21AU618AS camera. “It was the first light with this camera, I think it has passed the test.” Indeed it has.

Known as the Upside Down Astronomer, Paul recently got his new website operating, with amazing photographs, detailed info on his gear, and an ongoing blog of updates. Check out the detailed construction images of his green dome.

sun0012 12-33-22_g3_b3_ap193

A single frame of the animation, showing the power of the prominence on the Sun.

So what are we looking at here; what are these solar prominences? With all its twisting swirling gas, the Sun is surrounded by powerful magnetic fields which are constantly shifting, combining and snapping apart. Hot plasma (charged hydrogen and helium atoms) in the Sun’s atmosphere flows along the tangled structure of the magnetic fields. When these magnetic fields shift and snap, a tremendous amount of energy is released, and the plasma is blasted off into space. When these prominences are directed towards Earth, the stream of particles interacts with the Earth’s magnetic field to produce the beautiful auroras we see in the Northern and Southern latitudes.

Catching Sunlight: A TEDx Talk by DIY Solar Photographer Alan Friedman

Video poster frame shows Alan Friedman’s 90mm hydrogen alpha telescope setup — nicknamed “Little Big Man” — on an Astro-Physics 900 equatorial mount.

We’ve featured several beautiful images of the Sun here on Universe Today, captured by the talented Alan Friedman from his backyard telescope in Buffalo, NY. While photos of the Sun in and of themselves are nothing new in astronomy, Alan’s images always seem to bring out the best in our home star. Maybe it’s the magical nature of hydrogen alpha photography, maybe it’s Alan’s fancy new Grasshopper CCD camera, maybe the Sun’s photosphere was looking particularly nice on those days… but most likely Alan just has an innate skill for solar photography (as well as one for picking out great hats!)

In the video above, Alan talks to an audience at a TEDx event in Buffalo on October 9, sharing some of his photos and explaining why he does what he does, and why he feels do-it-yourself astrophotography is such a valuable thing to share with others. It’s a great bit of insight from a talented artist (and you just might recognize the names he drops at 13:55!)

I was happy to share one of Alan’s images on my own website back in 2010, which Phil Plait (the “Bad Astronomer,” who was then with Discover Magazine) picked up on and soon enough the whole thing got Alan quite a bit of attention. Which, when you’re an astrophotographer and graphic artist (he also sells art prints of his work as well as runs a greeting card studio) is never a bad thing.

Image of the Sun in hydrogen alpha. ©2010 Alan Friedman. All rights reserved. Used with permission.

You can see more of Alan’s work on his Averted Imagination blog and website and, on occasion, here on Universe Today!

SDO’s Camilla the Rubber Chicken: Cure for a Common Phobia

We at Universe Today really appreciate the work that Camilla the Rubber Chicken does in her role of education and public outreach. This new video from NASA explains why many people agree that she puts a completely different spin on getting people interested in space and science. As Camilla once told us, “As you know, I not only want to educate about our Sun and space weather, but I want to inspire and show kids (and adults) how much fun science and engineering really is,” she said via email. “Team SDO’s goal has always been to encourage more girls into STEM careers,” … and to make people feel comfortable asking questions, too.

STEREO Spots a CME Soaring Into Space

Press “play.” Say “wow.”

The enormous eruption of a solar prominence and resulting coronal mass ejection (CME) back on August 31 that was captured in amazing HD by NASA’s Solar Dynamics Observatory was also spotted by the Sun-flanking STEREO-B spacecraft, which observed the gigantic gout of solar material soaring away from the Sun.

This video shows the eruption as it passes across the fields of view of several of STEREO-B’s cameras over the course of 48 hours.

According to NASA’s Goddard Space Flight Center, “while CMEs are routinely seen in the Heliographic Imager (HI) telescopes, it’s very rare for prominences to stay visible for so long. The HI1 field of view ranges from 4 to 24 degrees away from the Sun. To get a sense of scale, we know the Sun is roughly 860,000 miles wide — and look how far the prominence holds together. And this CME is so bright it initially saturates the COR1 telescope.”

The bright spot in the red (COR2) field of view is the planet Venus.

Coronal mass ejections are huge bubbles of gas bounded by magnetic field lines that are ejected from the Sun over the course of several minutes — sometimes even hours. If they are directed toward Earth, the cloud of charged solar particles can interact with our magnetosphere and cause anything from increased auroral activity to radio interference to failure of sensitive electromagnetic equipment.

Particularly long filaments like the one that caused the August 31 CME have been known to collapse with explosive results when they hit the stellar surface.

The CME did not travel directly toward Earth but did connect with Earth’s magnetosphere with a glancing blow, causing bright aurorae to appear around the upper latitudes on the night of September 3.

Image: NASA/STEREO/GSFC

Google’s 5 Most Memorable Space Doodles

Google’s one of those tech companies that makes a big deal about space exploration.

There’s not only the Google Lunar X-Prize, or its maps of the Moon and Mars, or memorable April Fool’s pranks such as the lunar Google Copernicus Hosting Environment and Experiment in Search Engineering (G.C.H.E.E.S.E.)

The Mountain View, Calif.-based search giant often puts space front and center in its periodic “Google Doodles”, which are variations of its logo shown on the site. Google’s been pencilling those since 1998. Over the years the sketches have become more elaborate – and sometimes animated!

After reviewing the space doodles featured on Google’s Doodle site, here are five of the most memorable of them:

May 1-5, 2000 – Google Aliens series

 

This appears to be the first set of space-themed Google Doodles. The drawings are simple – for the most part, they show a UFO flying past or landing on the Google logo. Still, running them in a series over several days was smart, as it encouraged Internet users to visit the young search engine several days in a row to see what was happening next. More eyes on the page is always good for advertising.

Jan. 15, 2004 – Spirit lands on Mars

Mars landings are always big media events, and NASA was in the midst of a bonanza of attention in 2004 as both Spirit and Opportunity successfully touched down on the Red Planet. Thousands of Google users would have been searching out the rovers’ latest exploits. Commemorating Spirit’s landing in a doodle, just as that excitement was at a fever pitch, was a great way for Google to highlight the ability for users to seek out information about the rovers on its own site.

Aug. 9, 2010 – Anniversary of Belka and Stelka spaceflight

The best Google Doodles are those that show you what you don’t know before. In this case, few outside the space community are likely aware of who Belka and Stelka were, and where their spaceflight fits in history. (They were among a series of animal flights flown in the 1960s to determine the risks of space travel to humans.) From Google’s perspective, running a doodle one needs to learn more about encourages users to click on it, generating more page views.

June 15, 2011 – Total lunar eclipse, featuring Slooh

This is a brilliant example of cross-promotion. Astronomy geeks are well-aware of Slooh, a site that turns telescopes to celestial events such as the recent Venus transit of the sun. Google brought the site to the masses through promoting Slooh’s June 15, 2011 lunar eclipse feed right on the home page; the colour of the moon in the logo changed as the eclipse progressed. Google also showed the eclipse on its YouTube channel and on Google Earth, and promoted the Slooh Android app (also hosted by Google.) Slooh mentioned Google’s participation on its own website, too.

Nov. 8, 2011 – Edmond Halley’s birthday

Commemorating Edmond Halley’s birthday is not unique in itself, as Google has singled out other astronomers for the honour – see Ruby Payne-Scott and Johann Gottfried Galle, for example. What makes this sketch memorable is you can barely see the “Google” logo in the doodle. This is a company that is so confident in its brand that it is willing to let its readers fill in the blanks by imagination. (Astute readers will notice Scott’s doodle follows the same principle, but Halley’s doodle did run first.)

What other doodles should Universe Today readers check out? Share your thoughts in the comments.

All images are from Google’s Doodle website.

Elizabeth Howell (M.Sc. Space Studies ’12) is a contributing editor for SpaceRef and award-winning space freelance journalist living in Ottawa, Canada. Her work has appeared in publications such as SPACE.com, Air & Space Smithsonian, Physics Today, the Globe and Mail, the Canadian Broadcasting Corp.,  CTV and the Ottawa Business Journal.

Guest Post: Our Explosive Sun

Editor’s note: Pål Brekke is a Norwegian solar physicist with a doctorate from the University of Oslo in astrophysics and is now a senior advisor for the Norwegian Space Centre. He has written a new popular science book about the Sun, titled Our Explosive Sun; A Visual Feast of Our Source of Light and Life. Find out how you can win a copy of book here. Brekke has written this guest post for Universe Today.

The Sun has fascinated me for many years. This is perhaps not so strange since I walked my first steps at the solar observatory at Harestua, just north of Oslo. My dad worked there then. During my studies at the University in Oslo my advisors inspired me to spend time doing public outreach. And so it was my interest for sharing knowledge about the mysteries of the Sun that led to my writing this book.

This book presents the properties of the Sun, how it has fascinated humans for thousands of years, and how it affects our technological society. My hope is that this book will inspire an increased interest in the Sun and for natural science in general. The Sun is a perfect entrance to natural science, since it affects the Earth and humans in so many ways. Solar physics interacts with many other scientific fields, such as physics, chemistry, biology, and meteorology to mention a few.

The Sun


Caption: The Sun affects Earth in many ways. Image courtesy of Springer.

The Sun provides energy to all life on Earth and drives the climate system and is therefore very important to all of us. It powers photosynthesis in plants and is the ultimate source of all food and fossil fuel. However, storms on the Sun can also interfere with systems on Earth that our society depends upon.

Looking at the sky with the naked eye, the Sun seems static, placid, and constant. From ground the only noticeable variation in the Sun is its location (where it will rise and set today?). But the Sun gives us more than just a steady stream of warmth and light.

Situated 150 million kilometers away from us, the Sun is a huge thermonuclear reactor, fusing hydrogen atoms into helium and producing million degree temperatures and intense magnetic fields. Near the surface, the Sun is like a pot of boiling water, with bubbles of hot electrified gas. The steady stream of particles blowing away from the Sun is known as the solar wind. Blustering at 1.5 million kilometers per hour the solar wind carries a million tons of matter into space every second (that’s the mass of Utah’s Great Salt Lake).

Every 11 year the Sun undergoes a period of activity called the “solar maximum”, followed about 5 years later by a period of quiet called the “solar minimum”. During solar maximum there are many sunspots, and during solar minimum there are few. Thus, one way of tracking solar activity is by observing the number of sunspots. Sunspots are dark patches like freckles on the solar surface formed when magnetic field lines just below the Sun’s surface are twisted and poke through the solar surface. Sunspots can last from a few hours to several months, and a large sunspot can grow to several times the size of Earth. Though the Chinese recorded some observations as early as 28 B.C., scientists have been observing and recording sunspots since about 1610 when Galileo Galilei pointed his telescope towards the Sun.

Why do scientists care about Sunspots? Because they are visible signs of the turmoil inside the Sun that lead to space weather effects on Earth. Coronal mass ejections (CMEs) and solar flares are often associated with sunspot groups.

Over the next few years more solar storms will occur as the Sun approaches maximum activity in 2013.

Space Weather

Over the next few years more solar storms will occur as the Sun approaches maximum activity in 2013. And that sometimes these storms can cause damages here on Earth? In addition to creating the beautiful aurora, solar storms have many negative effects. The aurora is a manifestation of something violent happening in our atmosphere, where sometimes 1,500 gigawatts of electricity is generated. This is almost double the energy production in Europe!

Solar storms send out large amount of radiation, particles, gas, and magnetic fields into space, sometimes directly towards Earth. We are lucky that we are shielded from most of the hazardous radiation and particles. This is due to our atmosphere that is preventing UV and X-rays from reaching the ground, and our magnetosphere that is deflecting particles. The effects from solar storms are called space weather.

Until about 100 years ago solar storms could pass by without humans noticing much. However, today more than 1,000 satellites are operating in space. Our society depends on having these satellites work properly all the time. We use satellites for weather forecasts, communication, navigation, mapping, search and rescue, research, and military surveillance. The loss of a satellite and its signals can have serious consequences.

Solar storms affect important navigation systems and crucial radio communication. Passenger planes flying over the polar regions can lose radio contact with the flight controller. Satellite phones may stop working, and solar storms can knock out some electricity grids.

About the Author:

Pål Brekke has worked with state-of-the-art space-based solar telescopes since 1985 and has published over 40 peer-reviewed articles, 70 proceeding papers, and more than 30 popular science articles. For six years he was the ESA Deputy Project Scientist for the SOHO spacecraft.

Incoming! CME On Its Way Toward Earth

As you read this, a huge cloud of charged solar particles is speeding toward our planet, a coronal mass ejection resulting from the X1.4-class flare that erupted from sunspot 1520 on July 12. The CME is expected to collide with Earth’s magnetic field on Saturday, potentially affecting satellite operations and tripping alarms on power grids, as well as boosting auroral activity. It’s on its way, and all we can do is wait. (Thank goodness for magnetospheres!)

Actually, the effects from the incoming CME aren’t expected to be anything particularly dramatic. NOAA is predicting a geomagnetic storm level raging from G2 to G4, which although ranges from “moderate” to “severe” a G2 (Kp = 6) is most likely, according to Dr. C. Alex Young from NASA’s Goddard Space Flight Center.

[Read: What Is a CME?]

“A G2 level storm can cause some power fluctuations that may set off some voltage alarms for power companies,” Dr. Young told Universe Today. “Damage to transformers is possible for longer events, but unlikely. Satellite companies may have to make some orbit corrections for their satellites, and at higher latitudes where there are aurora they can be some disruption of high frequency radio broadcasts.

“All in all the effects should be minor,” he concluded.

And this may not be the last we hear from 1520, either.

“Its complexity has decreased but it is still large and has a ‘delta’ configuration,” added Dr. Young, “when there is opposite polarity magnetic field of the umbra within the penumbra of the sunspot. This is an unstable configuration that is indicative of larger releases of energy, lots of flares — in particular M and X flares.”

Below is a computer model of the CME from Goddard Space Weather Center. Impact with Earth is expected on 7/14 at 10:20 UT (+-7 hrs), 6:20 am EDT.

Auroras may be visible at lower latitudes this weekend, so check the NOAA’s updated auroral oval map to see if visibility extends into your area over the next several nights. Hopefully aurora photographers around the world will be able to get some great photos of a summer sky show!

You can keep up with the latest news on solar activity on Dr. Young’s blog, The Sun Today. And of course, stay tuned to Universe Today for more updates on any noteworthy space weather!

The video below uses SDO AIA footage in 131(teal), 171(gold) and 335 (blue) angstrom wavelengths, and shows the X1.4 class flare erupted from the center of the sun on July 12, 2012 at 12:52 PM EDT. Each wavelength shows different temperature plasma in the sun’s atmosphere. 171 shows 600,000 Kelvin plasma, 335 shows 2.5 million Kelvin plasma, and 131 shows 10 million Kelvin plasma. The final shot is a composite of 171 and 335 angstrom footage.

Top image: illustration of a CME about to impact Earth’s magnetosphere (NASA). Model animation: NASA/GSFC. Video courtesy NASA/SDO and the AIA science team.

UPDATE: The CME took a bit longer to arrive than expected, but impact with Earth’s magnetic field was detected at around 1800 UT (11 a.m. PDT/2 p.m. EDT), activating a geomagnetic storm. According to SpaceWeather.com: At the moment, conditions appear favorable for auroras over high-latitude places such as Canada, Scandinavia, Antarctica and Siberia. It is too early to say whether the storm will intensify and bring auroras to middle latitudes as well.

Sunspot 1520 Fires a Flare

Remember that cool animation I posted earlier of AR1520 and how I said there’s no guarantee it wouldn’t unleash an X-class flare? Well at 16:48 UT today, it did. Just goes to show there’s no guarantees in space!

The X1.4-class flare will most likely affect Earth’s magnetic field as 1520 is directly facing us. Stay tuned for more!

Video & image: NASA/SDO and the AIA science team.

UPDATE: The CME associated with this flare is expected to impact Earth’s magnetosphere on Saturday between 3 and 5 p.m. EDT with “moderate to severe” activity possible. See an animated tracker here. (H/T to Francis Reddy at GSFC.) Also in the lineup for impact are MESSENGER and MSL.

A Shimmering, Simmering Sunspot

This quick animation made by astrophotographer Alan Friedman shows a 30-minute view of sunspot 1520, a large region of magnetic activity on the Sun that’s currently aimed directly at Earth. Although 1520 has been quiet for the past couple of days, it’s loaded with a delta-class magnetic field — just right for launching powerful X-class flares our way. There’s no guarantee that it will, but then there’s no guarantee that it won’t either.

(Click the image to play the animation.)

Alan captured the images from his location in upstate New York using a 10″ Astro-Physics scope and PGR Grasshopper CCD. A master at solar photography — several of his hydrogen alpha images have been featured here on Universe Today as well as other popular astronomy news sites — Alan’s work never fails to impress.

A static, color version of sunspot 1520 can be seen here… what Alan calls “a magnetic beauty.”

Although the sunspots don’t change much over the course of the animation, the surrounding texture on the Sun’s photosphere can be seen to shift and move rapidly. These bright kernels are called granules, and are created by convective currents on the Sun. An individual granule typically lasts anywhere from 8 to 20 minutes and can be over 600 miles (1000 km) across.

The overall wavering effect is caused by distortion from Earth’s atmosphere.

While 1520 is facing Earth we’re subject to any flares or CMEs that may erupt from it, potentially sending a solar storm our way. In another week or so it will have rotated safely around the Sun’s limb and eventually dissipate altogether… but then, it is solar maximum and so there’s likely to be more active regions just like it (or even larger!) coming around the bend.

When they do come, there’s a good chance that Alan will grab some pics of those too.

Check out more of Alan’s photography on his site AvertedImagination.com.

Image © Alan Friedman. All rights reserved.

 

New Warning System Designed to Keep Astronauts Safe from Solar Storms

A new solar storm prediction system based in Antarctica could provide astronauts in space warning time of over two hours for them to take cover after massive flares or Coronal Mass Ejections erupt from the Sun. The South Pole Neutron Monitor is able to forecast the radiation intensity of solar protons using two different types of neutron detectors installed at the geographic South Pole, which measures gigaelectron volt neutrons that are produced during a solar storm.

The designers of the device have been testing it and say it could provide a warning times of up to 166 minutes, depending on the protons’ energy. Additionally, the team says, it is a practical system for forecasting peak intensity of solar energetic protons in the tens to hundreds of megaelectron volt energy range.

With activity on the Sun increasing as the Solar Maxiumum approaches, there will likely be heightened rates of flares and CMEs, putting at risk the human presence in space, which will likely be ever-increasing, with the advent of commercial space flights and NASA’s plans to send astronauts into deep space, along with crews of six that are usually on board the International Space Station. Even people in airplanes at high altitudes near the poles can be exposed to this increased radiation. Exposure can potentially cause radiation sickness, with symptoms such as fever and vomiting.

During a solar flare or CME, particles from the Sun can be accelerated to very high energies—in some cases traveling near the speed of light. Protons with energies surpassing 100 megaelectron volts essentially sandblast everything in their path.

S.Y. Oh from Chungnam National University in South Korea and an international team of researchers have created and installed the warning system at the Amundsen-Scott South Pole Station. Using one detector located indoors and another outside, they can measure the intensity of the much faster gigaelectron volt neutrons also produced during a solar storm when protons interact with Earth’s atmosphere. By combining the observations of the two detectors, they can then extrapolate this spectrum to estimate the peak intensity and event-averaged flux (fluence) of the later-arriving megaelectron volt protons.

The team compared their predictions for 12 solar events against observations made by geosynchronous satellites, such as some of the GOES satellites, and found their measurements were similar for intensity and fluence predictions for protons with energies higher than 40 and 80 megaelectron volts, respectively.

The researchers say the system could be useful for forecasting radiation hazard, because peak intensity and fluence are closely related to the known medical thresholds of radiation doses.

The lead times would allow for astronauts to take shelter in a shielded area of their spacecraft, or polar-flying airplanes ample time to reduce their altitude to be protected by Earth’s magnetic field.

Read the team’s paper: South Pole neutron monitor forecasting of solar proton radiation intensity

Lead image caption: The South Pole neutron monitor. Credit: University of Delaware.

Source: AGU