One of the more celebrated North Pole surfacings of the USS Skate happened today in 1959, see http://wattsupwiththat.com/2009/04/26/ice-at-the-north-pole-in-1958-not-so-thick/ for more on that and several others.
Nearly a couple years ago at the ICCC in Chicago, Lord Monckton noted that at the time of this surfacing it was late winter and the Sun hadn’t risen. I’m not entirely sure why he mentioned that, but I wasn’t able to come up with a quick and accurate description of the lighting conditions. Let me do it now so I can get the issue out of my system. First, we need a submarine:
I’m not about to spend my St. Patrick’s Day at the North Pole in hopes that a sub will surface, especially since there’s a perfectly accessible submarine in Portsmouth New Hampshire at Albacore Park. I go to an annual event in Portsmouth each February, which fit quite nicely into seeking photos set in an icy, snowy setting.
The rocket science part is to time the photo to match the Sun’s position below the horizon. At the North Pole the Sun rises in March and sets in September. The concept of a 24 hour day refers mainly to the longitude line the Sun is passing (it’s due south all “day” long).
Sunrise, by US Naval Office definition, is when the upper limb of the Sun touches the horizon. The USNO considers the horizon to be distant and the observer is close to land or sea surface. It’s fairly easy to compute the location of the center of the Sun relative the horizon as seen from the North Pole, it’s just the “declination,” which is the celestial equivalent of latitude. There are two significant effects to take into account. The obvious one is the Sun’s angular radius, which is about 16 arcminutes. The other is atmospheric refraction near the horizon. This is what makes the Sun and Moon look squashed when they are on the horizon. The refraction right at the horizon is about 34 arcminutes. So, sunrise occurs when geometrically the center of the Sun is 50 arcminutes (0.83°) below the horizon.
An aside – on the equinoxes, night and day are supposed to be equal. Not true! At most latitudes the time from sunrise to sunset is about 12h10m then. Today, for me, is the true clock time equinox.
Where were we? Oh yes. Some data from the North Pole on 1959 Mar 17, in degrees above the horizon:
1959 North Pole, Latitude 90.00 Longitude 0.00 Date Decln Mar 15 -2.32 Mar 16 -1.93 Mar 17 -1.53 Mar 18 -1.14 Mar 19 -0.74 Mar 20 -0.35 Mar 21 0.05
It would be nice to know the hour, but let’s not be that obsessive. What does this tell us? First, the Sun will rise around the 19th. Second, Spring begins when the declination is 0°, and that will be on the 21st. On the 17th, the entire Sun is below the horizon and the upper limb is 0.70° below the horizon. This puts us well into morning twilight. Twilight – what’s that? Let’s take a look from a North Pole point of view, and start when it’s just plain dark.
Another aside – at the start of winter at the North Pole, the Sun is 23.44° below the horizon. However, the Full Moon will be between some 18° to 28° above the horizon. Yes, it’s nighttime, but not completely dark all the time.
If we discount the Moon and clouds, the sky is dark at the start of Winter with only stars providing feeble light. In late January, the Sun climbs above 18° below the horizon and we enter Astronomical Twilight. This is a period where there is enough light from the Sun that it interferes with seeing faint objects in the sky, especially those nearest the rising Sun. In mid February the Sun reaches 12° and we enter Nautical Twilight. Brighter, but mariners can still easily see the stars used for navigation. By early March the Sun reaches 6°, now the navigational stars are fading from view and we’re in Civil Twilight and people can get around pretty well without extra light. From the above, we can tell Civil Twilight will last a couple weeks and then daylight begins.
Now, let’s shift our point of view to Portsmouth. I’m also shifting to the evening because I took these photos after sunset. Civil twilight here lasts about half an hour, which fits in well with both our experience and state motor vehicle law that requires headlights to be on by half an hour after sunset.
Another aside – twilight is longest at the Summer Solstice, shorter at the Winter Solstice, but shortest near the equinoxes. If there’s interest, I’ll go into more details in the comments.
My intent was to photograph the Albacore in lighting similar to what there was for the Skate, i.e. when the Sun was 0.70° below the horizon. The math for this is a bit trickier, and entails messing with declination, right ascension, latitude, longitude, and Solar altitude to get the date and time. A fine approximation uses just the date (I was there on 2010 Feb 20) and some of this data:
2010 Albacore Park, Latitude 43.08 Longitude 70.76 Date Rise Set Civil Naut Astro Decln Feb 21 6:32A 5:22P 0:29 1:02 1:36 -10.43
At sunset, the solar altitude is -0.83°, we want the time when it’s about -1.53°. We know during Civil twilight the Sun will drop 5.16°, so interpolating, that’s about 4 minutes after sunset, and gee, there should be plenty of light. While the the visitor center and Albacore were locked, I could park there and walk around the trench used to bring in the Albacore. And indeed, there was plenty of light, as the photos prove.
Just one other thing – yes, black and white films in the late 1950s were plenty fast enough. The photographer probably used Tri-X (ASA 400) or Royal-X (ASA 1200). The latter was so grainy that it generally was only used in large format cameras. I had my camera set to a ASA 400 (or maybe even 100) equivalent.
Lord Monckton has probably figured all this out, but now we all know that there was plenty light and we know where to find a submarine in a snowy environment.
The Albacore is an interesting vessel, several design experiments with it influenced the next generation of submarines.
A few weeks back in this thread there was this intriguing comment:
Sounds like a possible primary source. If you are still reading this thread could you elaborate on his status? If he is still with us perhaps you might arrange for an interview of him on the record so he can at least get his important eyewitness experience documented! Maybe he has his own private photos.
F.Y.I.
Here is an article of Life Magazine form May 4th, 1959: This tells us a lot on the conditions when surfacing at the north pole
http://books.google.de/books?id=YEgEAAAAMBAJ&pg=PA130&lpg=PA130&dq=skate+1959+arctic+journeys&source=bl&ots=Q3SNvUY9j0&sig=GBb9WYXOOntQ_VvyWeDr7uueJ6s&hl=de&ei=r0ClS4v_DsvDsgb8w_3JCA&sa=X&oi=book_result&ct=result&resnum=6&ved=0CB8Q6AEwBTgK#v=onepage&q&f=true
BR
MFKBoiulder
[Reply:Great find, thanks. The lead photo (split over two pages is one I hadn’t seen before.
The photo in the controversy is on page 135, and is identified as one of the 10 surfacings and clearly doesn’t match the conditions described in the article.]
Wow, I can’t believe I didn’t take the opportunity to mention that I worked for International Submarine Engineering for 6 years, when they made half of the total global underwater remotely operated vehicles (ROVs), as well as AUVs, USVs and other interesting projects, some classified perhaps 😉 .
The president, James McFarlane was in the navy before he started his company. I wonder what connections he still has.
http://www.ise.bc.ca/
The photo of the young sailor in the Bluenose ceremony from the Life Magazine article brings back memories. The missile sub I was on went north of the arctic circle twice. Being a missile sub on a cold war deterrent patrol, we didn’t go far north to go under the ice ( so far as I know).
This thread (and the related one the other day) is so cool. It has everything – humour, pathos, bathos, history, geography, astronomy, physics, engineering etc, and lots of anecdotes, some of which may even be shaggy dog stories. What’s not to like?
Never being afraid to ask a dumb question, I will bite on this:
“Another aside – twilight is longest at the Summer Solstice, shorter at the Winter Solstice, but shortest near the equinoxes. If there’s interest, I’ll go into more details in the comments.”
A lot of interest here – intuitively it would seem that twilight (and the opposite in the morning) waxes and wanes with the solstices. Plus, anecdotally, where I live (about 35 degrees south) the night falls like a brick in mid winter, in a few minutes. Just now, near the equinox, there is still some twilight. But perhaps I have missed something in the definitions?
On further thought, I am guessing that the point about twilights relates to longitude. They don’t have much at either end of the day near the Equator.
A photograph of the Skate during the actual event, takne by Commander James F. Calvert.
Hmmm, I will just leave a few pictures from the NOAA North Pole web Cam, showing the actual lighting conditions and shadows, depending on the seasons, at the pole, under clear weather conditions.
Link:- http://www.arctic.noaa.gov/gallery_np_seasons.html
How it works
The sun comes up each day because Earth rotates once on its axis every 24 hours or so. Seasons are a result of Earth being tilted 23.5 degrees on its spin axis coupled with the planet’s 365-day orbit around the sun.
The Arctic Circle, a line at 66 degrees north, marks the latitude at which the sun does not set during the summer solstice (when the top half of our planet is facing directly toward the sun), the longest day of the year, nor rise during the shortest day of the year, the winter solstice. The farther north you move from the line, the longer the period of night-less summer or sun-less winter. Ilulissat is located about 3 degrees north of the Arctic Circle, so residents spend the middle of winter without any sunlight.
At the North Pole, the sun rises only once a year — at the start of spring. It gets higher in the sky each day until the summer solstice, then sinks but does not truly set until late September, at the autumn equinox.
Here are some twilight notes. I like to look at various extreme situations, then show how they fit with in-between places and situations.
Let’s start at an equinox, if you want, assume the Earth isn’t tilted, then we’d be in a permanent equinox. The Sun will have a declination of 0° this means that the Sun is moving as fast as it can across the sky – 1° every 4 minutes. If you’re on the equator, the sun rises due East, passes overhead, and sets due south. Let’s just consider almost sunset (when the center of the sun is on the horizon (but appears to be a bit higher) and Civil Twilight (the period between the Sun setting and being 6° below the horizon.
At 1° per 4 minutes, it takes only 24 minutes for twilight to end. When the Sun sets at the equator, it heads straight down. At either pole, the Sun is still moving 1° per 4 minutes, but now the motion appears horizontal and the Sun just scrapes along the horizon. At temperate latitudes, the Sun is moving just as fast, but now it goes beneath the horizon at an angle, and the vertical rate is between what we saw at the equator and poles. That means twilight will lengthen as you get further from the equator..
In the summer, the sun still moves 360° around the sky, but given its 23.44° declination, it’s moving less that 1° every 4 minutes. This would be more obvious if the Earth had a bigger tilt. If we were nearly on our side, like Uranus, the Sun would make just a little circle around the Earth’s axis.
On the equator, the Sun still heads straight down, but at a slightly slower rate. More impressive is what happens in temperate latitudes. When the Sun has set, the path of its motion behind the Earth has its vertical component slowing. At Noon, the Sun was high in the sky, but in the afternoon it starts sinking faster and faster until about 6 PM when it begins to slow down and reverses at midnight. The Sun sets later than 6 PM, so at sunset its rate of fall has declined quite a bit. It also sets poleward of due west. So it makes a smaller angle as it crosses the horizon, and that reduces the vertical velocity too.
Ultimately, it takes more time to reach the end of twilight.
In the winter, the Sun sets while its descent is accelerating. It also sets equatorward of due west making a steeper angle as it crosses the horizon. These conflicting attributes wind up leaving the twilight longer than at the equinox, whereas in the summer, everything combines to make twilight longer than at any other day.