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Founded January 1970
Julian Date: 245955.16
2019-2020: CXXVII
THE DAILY ASTRONOMER
Thursday, April 16, 2020
Remote Planetarium 14: Starry Declinations and Right Ascensions
We complete the grid work today, ladies and gentlemen. Our focus today is the celestial sphere again. We will also use our knowledge about declinations to determine where any star can and can't be seen in the world.
Quick review of terms:
- Celestial equator: the projection of Earth's equator onto the sky
- Declination: the measurement of a celestial object's angular distance north or south of the celestial equator. Every object north of the celestial equator has a positive declination. Any celestial object on the celestial equator has a declination of 0. Every object south of it, a negative declination. The range is +90 degrees (north celestial pole) to -90 degrees (south celestial pole).
- Ecliptic: the Sun's apparent annual path through the sky.
TWO VIEWS OF THE ECLIPTIC
VIEW 1: The ecliptic appears to spend half the year (spring and summer) north of the ecliptic and the other half (autumn and winter) south of it. The ecliptic intersects the celestial equator twice, on the vernal and autumnal equinoxes.
VIEW 2: From our Earthbound perspective, the ecliptic is an undulating curve rising above and then sinking below the celestial equator. The Sun appears to follow this curve once a year. If we could see the celestial equator in our sky, we'd see the Sun "above" it in spring and summer and "below" it in autumn and winter.
- The celestial equator extends from due east to due west .
- The celestial equator attains its maximum height due south
- The celestial equator's maximum height depends on the observer's latitude. An equatorial observer would "see" the celestial equator pass directly overhead. (90 degrees above due south). A polar observer would "see" the celestial equator aligned precisely along the horizon (0 degrees above due south). To calculate the celestial equator's maximum height, subtract the observer's latitude from 90 degrees. For instance, Portland (ME) latitude is approximately 43 degrees North. The celestial equator's maximum height in Portland is 90 - 43 = 47 degrees
RIGHT ASCENSION
Let's say you're marooned on a deserted tropical island and for some reason you want to be rescued. What two pieces of information would you need to provide to someone through the satellite radio for them to pinpoint your location? Exactly. Latitude and longitude. Offering one without the other does little good. In order to locate a celestial object, one would also need two coordinates. We have already introduced "declination," the angular distance north or south of the celestial equator. Declination is the celestial equivalent to latitude, Now, we introduce the celestial coordinate that is equivalent to longitude: right ascension. Right ascension measures a celestial object's angular distance from the vernal equinox, the point where the ecliptic intersects the celestial equator on the first day of spring. While we measure declination in degrees, right ascension is measured in "hours, minutes and seconds." Any object along the arc corresponding to the vernal equinox has a right ascension of 0 hours. The range is 0 - 24 hours. However, 0 and 24 are technically the same point.
Let's look at two views of right ascension:
VIEW # 1: We see the right ascension as a circle running along the celestial sphere. Here again we're pretending Earth occupies the center of the Universe. The 0 h marks the vernal equinox, the point the Sun appears to occupy on the first day of spring. The 6 h mark corresponds to the point the Sun occupies on the first day of summer. The 12 hour point marks the Sun on the first day of autumn; 18 hours corresponds to the Sun's position on the first day of winter.
View 2: Using right ascension to pinpoint a star's location.
We can use this star chart to determine the coordinates of Orion's prominent stars. Betelgeuse, the star representing Orion's eastern shoulder, is nearly 8 degrees north of the celestial equator. Its declination is just about 8 degrees. Betelgeuse is also nearly at 6 hours east of the vernal equinox and so its right ascension is almost 6 degrees. (Look at the right ascension markers along the star chart's top.) The actual coordinates are Declination = 07° 24′ 25.4304″ Right Ascension = 05h 55m 10.30536s
Well, yes, we can hear some of you asking, "So, what?"
So, first of all, we needed to divide the sky this way so in future when we discuss celestial objects, we can specify their locations precisely.
Secondly, we can use declination to help us know which stars are and aren't visible from a given location. That is now our focus.
LATITUDE MATTERS!
An observer's latitude determines which stars will or won't be visible at his/her location. We can make those determinations ourselves by knowing a few rules and using just a minuscule amount of mathematics.
Refer to the graphic below when reading the list that follows.
- Any object north of the celestial equator is visible everywhere in the northern hemisphere. So, Betelgeuse, being nearly 8 degrees north of the celestial equator, is visible in all parts of the northern hemisphere. It is also visible in most of the southern hemisphere. (We'll explain where in a few moments.)
- Any object south of the celestial equator is visible everywhere in the southern hemisphere. Sirius, being nearly 17 degrees south of the celestial equator, is visible everywhere in the southern hemisphere and also in much of the northern hemisphere.
(We'll explain where in a few moments.)
- A star's declination is equal to the latitude where that star will pass across the zenith, the point directly overhead. For instance, let's pretend that Betelgeuse's declination is 8 degrees north. (It isn't, exactly.) Only an observer at the latitude 8 degrees N would ever see Betelgeuse pass directly overhead. As another example, let's also pretend that Sirius' declination is -17 degrees. (It isn't, exactly.) Only an observer at latitude 17 degrees S would ever see Sirius pass directly overhead. Here in Portland (ME), only stars with a declination of 43 degrees can pass directly overhead. The declination of Deneb, Cygnus the Swan's brightest star, is about 45 degrees north so it passes nearly overhead at this location.
- How to calculate a star's visibility region: We first subtract its declination from 90 degrees. We return to Betelgeuse, declination + 8 degrees (still pretending.). 90 - 8 = 82 degrees. As Betelgeuse is north of the celestial equator, it will be visible everywhere in the northern hemisphere. It will also be visible in the southern hemisphere down to the latitude of 82 degrees south. Anybody afflicted with a Betelgeuse phobia would want to live south of the 82nd southern parallel.
Let's work through some more examples:
- SIRIUS: Declination (almost) -17 degrees. 90 - 17 = 73. As Sirius is south of the celestial equator, it will be visible everywhere in the southern hemisphere. It will also be visible in the northern hemisphere up to latitude 73 degrees N. One won't see Sirius north of the latitude 73 N
- POLARIS: the north star's declination is 90 degrees (Almost. We're using round numbers so the math won't leave marks.) 90 - 90 = 0. Polaris is visible everywhere in the northern hemisphere down to the latitude 0 degrees, i.e. the equator. One won't see Polaris in the southern hemisphere. [Note: we use Polaris to approximate our latitude. If you're at 30 degrees N, Polaris will be 30 degrees above the northern horizon from your perspective.]
- VEGA: this star's declination is 39 degrees north (almost). 90 - 39 = 51. Vega is visible everywhere north of the latitude 51 degrees north.
Finally, we want to know where in the world a given star will be circumpolar, meaning always visible. That determination is wonderfully simple. Use the calculation you just performed to ascertain a star's visibility region and just reverse the sign. For instance, Betelgeuse is visible everywhere north of 82 degrees south. Well, Betelgeuse will only be circumpolar in regions north of 82 degrees north. Any observer north of 82 degrees north will always see Betelgeuse, when it is actually dark, of course. Sirius is visible everywhere south of 73 degrees north. So, Sirius will be circumpolar everywhere south of 73 degrees south.
What about Vega?
Vega is visible everywhere north of 51 degrees south. Vega will then be circumpolar everywhere north of 51 degrees north. We are less than ten degrees south of the region where Vega is always above the horizon.
Tomorrow, we'll offer more examples on the Week 3 quiz.
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