Author: cgino

The green flash. While at first, it may sound like the love child of two DC comic book characters, its name is actually much more literal. It’s a flash. That’s green. If you’ve seen Pirates of the Caribbean: At World’s End, you may be familiar with the idea. While Hollywood’s version of the green flash is massive and spectacular, the real life version (yes, there is a real life version) is much more subtle and easy to miss.

It can be seen for a brief moment on the horizon, right around sunrise and sunset when the conditions are right. But what are these conditions and what causes the last rays of sunlight to appear to us on Earth as a bright green?

Part of the answer lies in the refraction of light that happens in the Earth’s atmosphere. The most recognizable and well known example of light refracting is the rainbow. As sunlight makes the quick transition from air to water during its travel, the light is bent, or refracted, and separates out into all the colors contained therein (think Dark Side of the Moon album cover). You’ve also seen this effect if you’ve stuck a straw into a clear glass of water. The straw suddenly seems to defy physics and abruptly veers from its path so that the part above water appears to not quite connect to the part below water.

If you subscribe to our newsletter, you’ve also read about how we at the MROI have to deal with the atmosphere’s pesky tendency to refract starlight. In Project Scientist Michelle Creech-Eakman’s Instrumentation Station article titled What is a Delay Line and Why Do We Need Ten of Them?, she likens the light emanating from the stars to a sheet of paper with a picture on it. At first the picture is flat and perfect. But as this light paper reaches our atmosphere, the light paper begins to crumple and distort. To find out how that light paper gets flattened back out into an image we can see, take a look at Dr. Creech-Eakman’s article in the June newsletter.

But back to the green flash. As with the rainbow, one effect of this bending is for light to be separated into its distinct wavelengths: different colors. The green light is the color that is in our line of site while the rest of the colors dip below the horizon, thus: a green flash.

While the green flash is most commonly observed when looking out across the ocean, it can be seen from anywhere in the world. It is easiest to see when the observer has an unobstructed view of the horizon and the air is clear and still. Next time you happen to be outside right before sunrise or right after sunset, take a look and see if you can spot it! This is not a suggestion to stare directly at the sun. Wait for the moment just after the sun has set or the moment just before it rises. We can’t promise any souls will return to Earth as was signified by the appearance of the green flash in the Pirates movies, but we can guarantee it’s a pretty neat sight!

Article by Shelbi Etscorn of the Magdalena Ridge Observatory Department of Outreach and Communications.

A brave woman armed with the specialized tools of her trade sits alone in the dark and mentally prepares herself for the hunt. Her mission: to track down and identify some of the more elusive and exotic members of our solar system.

No, this is not an opening scene from Buffy the Vampire Slayer. This could be you or me, a citizen scientist, using Photoshop to animate a set of images from one of NASA’s orbiting solar observatories to hunt for comets.

A few days back we learned about famous comet hunter Charles Messier and how his catalog of objects came about. By participating in one of NASA’s Citizen Science projects, you too can become a comet hunter even if you don’t have access to a telescope!

Enter NASA’s Sungrazer Project, where you can put your hunting skills to the test and hopefully discover a comet. Participants inspect images taken by the ESA/NASA Solar and Heliospheric Observatory (SOHO) or NASA Solar Terrestrial Relations Observatory (STEREO) and look for objects moving in such a way that they may be comets. To date, over 4,000 comets have been discovered in SOHO data, with the majority of those found by citizen scientists. Moreover, over 99% of SOHO’s comet discoveries have come from its LASCO coronagraph, an instrument that uses an occulting disk to block the direct light from the sun, allowing faint objects in the vicinity of the sun to be visible.

Want to get involved in the hunt? You would start by downloading a set of SOHO/LASCO still images, then animate the images using a program such as Photoshop or GIMP. When you view the animation, you’ll see a lot of moving objects, most of them stars or sometimes a planet. It’s easy to rule out the stars in the SOHO/LASCO image animation because they always move horizontally from right to left and at the same speed as one another. Planets are easily identifiable as well, since they always move horizontally either right to left or left to right, and they are generally larger and brighter than stars. Another common sight will be cosmic rays, energetic particles striking the imaging sensor. Again, these are easily identifiable because they appear in only one frame of the animation as white dots, blobs, or streaks at random locations in the field of view. To get an idea of what you’re dealing with, click on the image below to view an animation of recent SOHO/LASCO data. It’s easy to identify the stars, a planet, and a multitude of cosmic rays.

The tricky bit is finding a comet in the midst of these predictably and chaotically moving objects. You are looking for a small, faint dot moving slowly through the animation, usually toward the Sun from the lower portion of the field of view. Comets are easily distinguishable from stars and planets, as they hardly ever move horizontally through the images, and they always move with a near constant speed, size, shape, and brightness. This small, faint, slowly moving dot must appear in at least five consecutive images before being reported as a potential comet. To find out if comet hunting is for you, download a sample set of data that includes a known comet (available at the bottom of this comet hunting guide web page), and see if you can pick it out of the crowd of stars, planets, and cosmic rays.

Comets not your cuppa? No problem! You can search for exoplanets, spot protoplanetary disks around nearby stars, or process and analyze images of Jupiter. Prefer to use your own telescope? You can submit data on the brightness and position of near Earth objects, or share your Jupiter images with the JunoCam team to help them plan future photographic missions.  

NASA’s citizen science projects are not limited to astronomy; you can find projects in the fields of geology, oceanography, meteorology, and more. Moreover, citizen science projects aren’t limited to NASA; use your computer’s down time to analyze radio telescope data for SETI, classify distant galaxies for Galaxy Zoo, help identify constellations in celestial maps for the Adler Planetarium, or transcribe the notebooks of the famous Harvard College Observatory women “computers” for the Smithsonian. The number of crowdsourcing projects continues to grow!  

Next time you have time to kill, why not stop your Pokémon Go, close your Candy Crush, and spend some time contributing to scientific research. Below you’ll find more links to help get you started on your own hunt:

https://www.zooniverse.org/projects

https://transcription.si.edu/

https://www.scientificamerican.com/citizen-science/

https://www.oldweather.org/

http://www.cosmologyathome.org/

https://einsteinathome.org/

https://www.uahirise.org/hiwish/

https://www.zooniverse.org/projects/nora-dot-eisner/planet-hunters-tess

http://scope.pari.edu/

https://www.zooniverse.org/projects/shannon-/solar-stormwatch-ii

https://www.aavso.org/observers

http://alpo-astronomy.org/lunarupload/lunimpacts.htm

Happy Hunting!

M. Colleen Gino, MRO Assistant Director of Outreach and Communications

Once again we get to hear from MRO Outreach Assistant Shelbi Etscorn!

Have you ever searched for something in a cluttered purse or backpack and found that your hands seemed to be predisposed to grab every object except the one you’re looking for? You dig and dig, and your impatience grows with every passing second. If you’re like me, your frustration and agitation will eventually lead to you pulling out items one by one just to get them out of the way while you focus on finding the one thing you’re looking for. For most of us, the outcome of this labor is simply the retrieval of the object in question and perhaps a sense that you might want to consider cleaning out your bag. But when French astronomer, Charles Messier, applied this same concept to his hunt for comets, he ended up creating one of the most famous lists of astronomical objects ever compiled.

During the 17^th century, Messier became the first astronomer to dedicate himself wholly to searching the night sky for comets. It proved to be a pursuit he was very adept at, earning him the title of the Comet Ferret by King Louis XV.

While scanning the sky searching for new apparitions, Messier came across the Crab Nebula, a supernova remnant in the constellation Taurus. His excitement at finding what he initially mistook as a comet, quickly turned to frustration when he realized his error. To avoid being hoodwinked again, Messier jotted down the location of the object. He was effectively pulling the Crab Nebula out of the night sky and setting it to the side so it would not disturb his quest, much like the clutter pulled out of the bag.

It wasn’t until Messier added his third entry to his list of objects to disregard, that he began to actively search for these objects in the same way he had previously searched for comets. What he once saw as a mess was quickly becoming his masterpiece.

By 1771, Messier had compiled a list of 45 objects that had been discovered by himself and by his contemporaries. This initial catalogue was published in 1774 in the journal of the French Academy of Sciences.

By 1780, the catalogue had grown to include 80 objects.

By 1781, Messier published his final version which held 103 celestial objects.

The Messier catalogue as it is known today contains 110 objects. After his death, astronomers were guided by Messier’s notes to find the final seven contributions to the catalogue, the most recent of which wasn’t added until 1967. Among the catalogue can be found examples of all five types of deep-sky objects: diffuse nebulae, planetary nebulae, open clusters, globular clusters, and galaxies.

While Messier’s catalogue only includes objects visible from the European latitudes (being the objects which Messier could observe), it is still an extremely popular list for amateur astronomers and researchers alike owing to the fact that all of these objects are among the brightest, nearest, and most easily found objects in the sky. Messier was able to find them all using a 4-inch refracting telescope. Today, even basic telescopes available to amateur sky enthusiasts are capable of observing these objects with great detail.

Because of this, they have become some of the most popular objects observed during star parties, shot by astrophotographers, and researched by scientists. Even if you know very little about astronomy, chances are you’ve heard of at least one of these objects: The Andromeda Galaxy, the Orion Nebula, the Pleiades, and the Whirlpool Galaxy just to name a few. All of the heavy hitters of the astronomical world make the list. It reads like the who’s who of astronomical objects.

The next time you look up at the night sky, take a look at Messier’s catalogue and see if you can’t find a few. You’ll inevitably find yourself looking at some of the most beautiful objects in the night sky. The story of Messier and his catalogue is an excellent reminder to not become so focused on the task at hand that you are unable to see what beauty may lie in the road bumps along the way. You never know when the pebble in your shoe might prove to be gold. Unfortunately, at the time of writing this, the clutter found in the mayhem of my purse remains: clutter. ­­­

Or at least observe a few…That’s right, it’s time for the annual Perseid meteor shower, whom most agree puts on the best show for those of us in the northern hemisphere. The Perseids are predicted to peak on August 11 – 12. This year the celestial light show may be somewhat subdued due to the nearly last quarter Moon rising not long after the radiant of the shower in the constellation Perseus. Many of the fainter meteors will be lost in the glare of the Moon, but one should still see plenty of bright meteors, up to 50 an hour, and maybe even a fireball or two.

An annual meteor shower is one that occurs every year over the same period of time in a well-defined area of the sky. In the case of the Perseids, the meteors appear to come from the constellation Perseus. Meteor showers are named after the constellation that the radiant appears in, the radiant being the point in the sky in which the meteors appear to originate from.

Meteors are little bits of debris (ranging in size from a grain of sand to a small pebble) left behind by comets and asteroids that strike the Earth’s atmosphere and burn up in a fiery streak of light. On any given night and depending upon your observing conditions, you can expect to see a handful of meteors coming from random directions in the sky, called sporadic meteors. Annual meteor showers occur when the Earth passes through the trail of debris left behind in the orbital path of a comet. The Perseids are from Comet Swift-Tuttle, a periodic comet that passes through our neighborhood every 133 years.

The brightness of a meteor depends both upon its size and the speed at which it passes through our atmosphere, with speeds ranging from 25,000 to 160,000 mph. Since the range of sizes of a meteor is pretty small, less than 1 to 2 grams on average, the kinetic energy the particle has due to its speed is the dominant factor in how bright it will appear. The flash we see from Earth is due to the tiny piece of debris transferring its energy to atmospheric atoms along its path as it travels through the thermosphere (the meteoric region lies about 50 to 75 miles in altitude). This long, thin column of excited atoms, the meteor trail, is usually less than several feet in diameter but can be dozens of miles long.

The best time to look for Perseids is after midnight into the early morning hours of Wednesday, August 12. The sky map above shows the location of the radiant at 1:00 AM MDT for our location here in Socorro, New Mexico. Not a night owl? No problem! You can start your search as soon as it gets dark; set yourself up in a comfy lounge chair, look toward the northwest, and you will likely catch a glimpse of a falling star.

M. Colleen Gino, MRO Assistant Director of Outreach and Communications

Check out our three new astrophotography desktop wallpapers! Visit the MRO website to download the full-sized versions!