17,500 Years In The Making – A Small Contribution To The 3rd Edition Of “Star Maps: History, Artistry, and Cartography”

Above: One of my all-time favorite images – a mural within the Lascaux Caves, possibly depicting three (now) prominent asterisms in the nighttime skies of winter.

I had been forwarded along a link from the now-defunct spacetoday.org site back in ’08 or ’09 about a possibly astronomical origin to one particular wall painting within the Lascaux Caves in southwestern France. Someone, either in an expedition or with photos from the documentation, must have had some amateur astronomy background (because most professional astronomers only enter caves when they’re obtaining data) and noticed that the groupings of stars on either side of one connect-the-dots now-extinct auroch (note the timing here – the bull is, astronomically-speaking, a later invention) had the right placement – and nearly the right counts – to maybe, kinda, sorta, possibly be as if someone had drawn the Orion Belt stars (and their collective +1) and a 25x zoom of our second-closest open cluster – the Pleiades (M45) – on either side of a cluster of black dots on an auroch’s head that could represent our closest open cluster – the Hyades.

This type of ancient astronomy history sticks *hard* in my brain, leading to the usual scouring of information online for other reports, images, refutations, etc. This then lead to my including the story way back in a November, 2009 constellation-of-the-month article for the SAS’s Astronomical Chronicle and, with clarifying image, in the December 2016 article of the short-lived Upstate New York Stargazing series.

For someone wanting the unmodified image from the mural, there remains a high-res download available from baerchen3.wp.com.

It should come as no surprise that our ancestors would want to take the most mystical part of their day – the night – inside with them. There is no shortage of civilizations combining small clusters of stars in the sky with fantastical stories (see: the Northern Constellations), and seeing patterns in otherwise random visuals has probably been a solid feature in our brains far longer than any crafted image we’re likely to find buried in any ancient community (see: Pareidolia).

Above: A screencap of the relevant image and associated star chart from “Star Maps: History, Artistry, and Cartography.” Click for a larger view.

If, in fact, this mural was intended to represent the arrangement of what we know as Orion’s Belt, what we know as Taurus the Bull, and what we now call the Pleiades, it raises a host of questions. Is there somehow a direct, herd-migratory line from this cave painting to the walls of Babylon and into early western mythology? Was there a single painter? Was the head or were the stars painted first? If more than one person did it, same question – did someone add the stars to a head, or add the head to the stars? If we looked hard enough on either side of the current belt in the nighttime sky, would we see remnants of a far distant supernova in the background that might have appeared to the cave dwellers as a new, bright fourth star? Alternatively, how much trouble did Ukleois (remember, he’s French) get into by adding the fourth star to the Belt? Did the painter, intending to remove the fourth star after admonishing Ukle-çois for his vandalism, die in a violent way during the morning hunt for breakfast, leaving the fourth star there for all time? Is the right-most or the left-most fourth star the wrong one? Did anyone take fingerprints of these two stars to see which was different from the middle two to know which was the unwanted addition? Was the painting a deep thought of artistic expression by Jean-Ukle that should be deeply read into as a marker of Paleolithic human endeavor, or was it a particularly miserable rainy Tuesday night and Jean-Ukle was simply lamenting not being able to enjoy a bucolic moonlight stroll by spending the evening instead scribbling on a flat piece of cave while getting mildly blotto from the carbon monoxide?

We may never have the answers to these questions.

In the meantime, I have ended up contributing to the astronomical literature in the tiniest of ways to this earliest of anti-memes (because it did not come to you – you had to go to it) in the newly printed 3rd Edition of Nick Kanas’ excellent (e)book “Star Maps: History, Artistry, and Cartography,“ available at amazon and wherever fine Springer Praxis books are sold.

He’s a fellow amateur astronomer, so I liked him already. Additionally (from the amazon bio)…

Dr. Nick Kanas is an Emeritus Professor of Psychiatry at the University of California, San Francisco, where he directed the group therapy training program and wrote a book entitled Group Therapy for Schizophrenic Patients. For over 20 years, he conducted research in group therapy, and for over 15 years after that he was the Principal Investigator of NASA-funded psychological research on astronauts and cosmonauts. In 1999, Dr. Kanas received the Aerospace Medical Association Raymond F. Longacre Award for Outstanding Accomplishment in the Psychological and Psychiatric Aspects of Aerospace Medicine. In 2008, he received the International Academy of Astronautics Life Science Award. He has over 230 scientific publications.

Dr. Kanas is the coauthor of Space Psychology and Psychiatry (now in its 2nd edition), which won the 2004 International Academy of Astronautics Life Science Book Award. In 2015, he authored Humans in Space: The Psychological Hurdles, which won the 2016 International Academy of Astronautics Life Science Book Award. 

Dr. Kanas has been an amateur astronomer for over 50 years. He has collected antiquarian celestial maps for over 30 years and has given talks on the history of celestial cartography to amateur and professional groups.  He is the author of Star Maps: History, Artistry, and Cartography (now in its 2nd edition), and Solar System Maps: From Antiquity to the Space Age. An avid science fiction reader, Dr. Kanas has given talks and participated on panels at numerous World Science Fiction Conventions. He has published articles for Analog Science Fiction and Fact magazine and won the Analog AnLab 2015 readers’ poll award for Best Fact Article of the year. He has published three science fiction novels for the Springer Science and Fiction series: The New Martians, The Protos Mandate, and The Caloris Network. Except for his group therapy book, all of his books are published by Springer.

Check his website (nickkanas.com), follow him on twitter (@nick_kanas), give a listen to an interview on The Space Show (and subscribe and support it, as it is excellent), and go buy a copy of the book.

“November Stargazing In Upstate” And “Upstate NY Stargazing In December” Articles Posted To newyorkupstate.com And syracuse.com

They’re still settling on the title.

2016 has been a looooong year in many respects (and I’m not even taking about Bowie, Prince, Cohen, Hutcherson, Bley, Glass, Schulten, Minksy, and now Glenn, to name but a few), made all the more difficult by many of the most significant events happening without warning and/or adequate statistical analysis.

Amateur astronomers, on the other hand, have had thousands and tens of thousands and maybe millions of years of advanced notice that 2016 was going to stink – at least for meteor showers. The timing of Full Moons this year has meant that the Perseids, Leonids, and Geminids were all going to occur in the presence of considerable lunar glow, wiping out the quality of all but the brightest shooting stars.

So, how doe one remain optimistic in the face of physics?

One possible way is to thank the gods for astrology. I’ve struck an ambivalent tone of sorts this year with the new Upstate NY Stargazing series concerning this thing we call the “Supermoon.”

Does a supermoon mean anything scientific? Meh, minus an inch or so difference in tides during the best of them. Do supermoon articles in the local papers receive attention? The Supermoon “likes + shares” kick the dark side of the Moon out of the monthly overview articles – which means people are reading and out-and-about taking pictures of our nearest and most important satellite. And so, there it is.

The November article, which I completely forgot to post about last month, included a new section announcing UNY/CNY observing opportunities with local clubs and organizations (Bob Piekiel reports that his November attendance was excellent!) and some subtle observing opportunities for those with decent binoculars. This was also the last good month for any observing of objects in the Summer Triangle, (meaning I have to think of a different shape for next year to keep the articles fresh).

* syracuse.com/outdoors/2016/10/november_star…

* newyorkupstate.com/outdoors/2016/10/november_star…

The featured constellation in the December article gave me an opportunity to write about something I’ve lectured about since 2009 (when I started the Liverpool Public Library and Beaver Lake circuit). Of all of the delights in the nighttime sky, none stop me cold like the view of Orion and Taurus comfortably above the horizon. The December article gave a perfect opportunity to highlight the near-recent history of this part of the sky in light of discoveries in the Lascaux Caves in France.

Half of the image at top (you can find the original and many others at baerchen3.wordpress.com/2012/06/20/la-grotte-de-lascaux/. And, I ain’t gonna lie, someone spent an awful lot of time on the following: 19thpsalm.org/Ch01/LascauxSkyChart.html) has made up one desktop background on my MBP for quite some time – the figure of a Bull, complete with a number of dark spots strategically placed as if the artist – or someone soon after the artist – meant to overlay the most prominent, eye-catching stars in the Orion-Taurus grouping on top. Pareidolia and our common genetics being what they are, it would not be surprising that many cultures would see a bull’s head out of the Hyades and Aldebaran, just as they’d see Orion as a human figure. What would be a surprise was a discovery that our modern Taurus and this ancient cave painting were directly related through time, migration, and story telling around open fires – a 17,500 year long game of celestial telephone.

* syracuse.com/outdoors/index.ssf/2016/12/upstate_ny_star…

* newyorkupstate.com/outdoors/2016/12/upstate_ny_star…

Some Light Science Reading. The Constellations: Taurus

As first appeared in the November 2009 edition of the Syracuse Astronomical Society newsletter The Astronomical Chronicle (PDF).

Constellation Map generated with Starry Night Pro 6.

This month’s constellation is one of the best in the Night Sky for combining ancient tradition, mythology, modern astronomy, world history, stellar eye candy, and even modern engineering into one reasonably small bordered pen of celestial real estate. The early evening sight of the constellation Taurus the Bull in the November southeast sky at Darling Hill might appear to CNY viewers as a snow divining rod pointing to the western Great Lakes in anticipation of winter and the upcoming lake-effect snow. Taurus is a distinctive constellation and very easy to identify once its central asterism is identified. The brightest star in the constellation is almost equidistant from the easily identified Pleiades and the shoulder of the constellation Orion, the celestial hunter Taurus is running from as the sky appears to move (or, from the most commonly drawn orientation, right towards him!). While Taurus is mildly sparse in quantity when it comes to dark sky objects, it more than makes up for it in quality, hosting two of the most significant stellar sights in the Night Sky.

Like its neighbor Orion, Taurus the Bull is a very, very old constellation and has been recognized as a bull for the duration of its existence in Middle Eastern and European traditions. Earliest records of any kind place the birth of Taurus in the Copper (Chalcolithic) Age (4500 – 3500 B.C.E.), although some records support its existence even earlier. The presence of a bull and what appears to be a Pleiades-like star formation exists on a wall in the Lascaux Caves of France (see right). Although the interpretation of the Constellation set is controversial, this arrangement may date back as far as 16,500 years. Personally, I find even the thought of that kind of continuity between what we might see in the winter skies and what our ancestors also saw at night both comforting and humbling. Many of the same stand-out patterns we know today no doubt stood out immediately to them as the brightest objects in the sky marked out regular places as the Sun set, and the great distance we’ve traveled in history might be barely perceptible to an ancient astronomer going simply by the positions of stars.

Lascaux Cave bull and star pattern. From the Institute for Interdisciplinary Studies and spacetoday.org.

We begin the tour by aiming our sights at the bright eye of the bull, the star Aldebaran. This orange giant is 44 times the diameter of our own Sun and has already used its hydrogen fuel, leaving this fusion engine to now graze on a steady diet of helium. Its name is derived from the Arabic for “the follower,” often reported as in reference to its position below the Pleiades (so “following” this open cluster as we progress into winter). The other stars in Taurus are easy to see in darker skies but not otherwise noteworthy for their brightness at either naked-eye or binocular viewing magnification. Several of the bright stars closest to Aldebaran make up an asterism that a new observer might confuse with the complete constellation. The V-shaped Hyades (center of the image below and shown at right with white border) are composed of five stars, with Aldebaran the brightest tip. I’ll admit that the first time I marked out the space for Taurus, I confused this asterism (and lambda-Tau to the west) with the entire object before double-checking the size. No bull. The Hyades star closest to Aldebaran, theta-Tau, is actually a pair of pairs, although they only appear as a single bright pair in binoculars and telescopes.

The Hyades (white) and Pleiades (red). From Lynn Laux, nightskyinfo.com.

Caught within the bull pen is the Pleiades (M45, shown labeled below from a Hubble image). This Tiny Dipper is visible year-round during the daytime in parking lots and slow-moving traffic everywhere (as the object embedded within the emblem on every Subaru, the Japanese name for this asterism) and is one of the treats of winter viewing in CNY (unless VERY early morning viewing is your game or you’ve been trying to see Mars in the late Summer skies, in which case you’ve been enjoying the pre-dawn sight of M45 since August). The amount of information available on the Pleiades online and as part of space research could easily (and very likely has) fill an entire book. While the seven bright stars are identified from Greek mythology as the Seven Sisters (Sterope, Merope, Electra, Maia, Taygete, Celaeno, and Alcyone), the counting aid that comes from a pair of binoculars easily reveals nine stars. The two stars that make up the handle of this tiny dipper are the proud parents Atlas and Pleione, placed to the east of the dipper to protect their daughters from either Taurus (for being a bull) or Orion (for being a male). Given the long history of this asterism, it is perhaps not surprising that the parents decided not to stop at seven. In fact, there are over 1,000 distinct stars in the Pleiades that have been revealed as part of multiple high-resolution studies. This density of stars makes the Pleiades a unique open cluster, as there is a wealth of stars and patterns visible at virtually any magnification, from small binoculars to the largest ground-based telescopes. For my first proper viewing session, I spent one full hour simply looking at this cluster through my Nikon 12×50’s, amazed at just how little we really see of the Night Sky using the 1×7 binoculars built into our heads (and, perhaps, corrected by horn-rimmed glasses).

The Pleiades in detail. Image from hubblesite.org and wikipedia.org

On the opposite side of Taurus and caught between the horns is the first of the categorized Messier objects, the Crab Nebula. M1 to its friends, this nebula is a supernova remnant with a remarkable history. As documented in both Arab and Chinese texts (Europe was just coming out its, er, Dark Ages at the time), this supernova was so bright on July 4, 1054 that it was visible during daylight hours (and, as you can guess by the date, visible without any magnification). The supernova remnant we know today as the Crab Nebula was discovered (and correlated to the original supernova) first by John Bevis in 1731, then by Charles Messier in 1758 while, as it happens, observing a comet (that Messier is known best for his catalogue of objects that were NOT comets instead of the comets he worked so diligently to discover is one of the great fun ironies of astronomy). The NASA images of the Crab Nebula reveal a dense sponge-like structure full of filaments of all sizes. The image above shows a remarkable sight – the full cycle of the pulsar at the heart of the crab that continues to magnetically drive the expansion of the nebula (in the series of frames, the pulsar lies below and to the right of a constant-brightness star).

The Crab Nebula pulsar. Image from www.strw.leidenuniv.nl

Stepping forward several hundred years, Taurus also marks the present locations of Pioneer 10 and COSMOS 1844. Pioneer 10 is currently speeding in the direction of Aldebaran, having been successfully steered through the asteroid belt to make a series of images of Jupiter. At its current velocity, this trip to Aldebaran’s current location would take 2 million years, about the same amount of time it might take most of the world to decipher the meaning of the emblematic plaque attached to its exterior (below). Perhaps someday we’ll have to explain to the aliens how a civilization that could launch a complicated probe into space couldn’t see the multitude of planets in their own Solar System, then perhaps have to explain what happened to Pluto hat it no longer appears in our Solar System images. COSMOS 1844 is one of over 2440 satellites launched by the Soviet Union (and now Russia) since the first of the COSMOS series in 1962. At mag. 5, this satellite makes for a fun artificial viewing target (with a good map in hand).

The Pioneer 10 plaque. From wikipedia.org.

The final sights for telescope viewers include four NGC objects. NGC 1746, 1647, and 1807 are open clusters with magnitudes between 6 and 7. NGC 1514 (below) is a mag 10 planetary nebula just at the far edge of the Taurus border that should be increasingly good viewing as Taurus works its way towards our zenith (1514 will be the closest it will get to our zenith by midnight, a perfect last-good-look before Darling Hill completely freezes over).

NGC 1514. From Martin Germano, seds.org)

Phenomenal viewing at a reasonably safe distance. Just be mindful not to wave your red flashlights at Aldebaran!

www.syracuse-astro.org
http://en.wikipedia.org/wiki/Taurus_%28constellation%29
http://en.wikipedia.org/wiki/Divining_rod
http://en.wikipedia.org/wiki/Great_Lakes
http://en.wikipedia.org/wiki/Lake_effect_snow
http://en.wikipedia.org/wiki/Orion_%28constellation%29
http://en.wikipedia.org/wiki/Chalcolithic
http://en.wikipedia.org/wiki/Lascaux_Caves
www.spacetoday.org/SolSys/Earth/OldStarCharts.html
http://en.wikipedia.org/wiki/Aldebaran
http://en.wikipedia.org/wiki/Hyades_%28star_cluster%29
http://www.nightskyinfo.com/archive/hyades/
http://en.wikipedia.org/wiki/Pleiades_%28star_cluster%29
http://www.subaru.com/
http://en.wikipedia.org/wiki/Mars
http://en.wikipedia.org/wiki/Sterope_(Pleiad)
http://en.wikipedia.org/wiki/Merope
http://en.wikipedia.org/wiki/Electra_(Pleiad)
http://en.wikipedia.org/wiki/Maia_(mythology)
http://en.wikipedia.org/wiki/Taygete
http://en.wikipedia.org/wiki/Celaeno
http://en.wikipedia.org/wiki/Alcyone_(star)
http://en.wikipedia.org/wiki/Atlas_(mythology)
http://en.wikipedia.org/wiki/Pleione_(mythology)
http://en.wikipedia.org/wiki/Crab_Nebula
http://en.wikipedia.org/wiki/Dark_Ages
http://en.wikipedia.org/wiki/John_Bevis
http://en.wikipedia.org/wiki/Charles_Messier
http://www.nasa.gov
http://www.strw.leidenuniv.nl/~oberg/Pulsars/external.html
http://en.wikipedia.org/wiki/Pioneer_10
http://en.wikipedia.org/wiki/Jupiter
http://en.wikipedia.org/wiki/Pluto
http://en.wikipedia.org/wiki/Cosmos_%28satellite%29
http://en.wikipedia.org/wiki/Pioneer_plaque
http://server1.wikisky.org/starview?object_type=4&object_id=241&object_name=NGC+1746&locale=EN
http://server1.wikisky.org/starview?object_type=4&object_id=211&object_name=NGC+1647&locale=EN
http://server1.wikisky.org/starview?object_type=4&object_id=279&object_name=NGC+1807&locale=EN
http://seds.org/~spider/ngc/ngc.cgi?NGC1514