Midterm 1 Flashcards
Zenith
The point directly overhead (based on a persons location standing on the earth)
Altitude
The height of a star above the horizon
Solstice
The date in the Northern hemisphere when the Sun is as high in the sky as it gets (Summer solstice - June 21)
-also highest point above celestial equator
-lowest in winter sky is the winter solstice (Dec. 21)
Caused bc of the tip of the earth
Ecliptic
The path of the Sun through the sky over the course of a year
- moon and planets remain near this line
- bc of the 23 degree tip of the Earth’s axis, the Sun doesn’t follow the celestial equator
Meridian
A line form due north, through Zenith, to due South
-based on your location on earth (diff. depending where you are - whereas equator and poles are always the same)
Equinox
The point where the ecliptic crosses the celestial equator
- Vernal Equinox (Mar. 21)
- Autumnal Equinox (Sept. 21)
- represent beginning of spring and fall
Celestial Equator
The extension of the Earth’s equator onto the celestial sphere
Azimuth
An angle measured from due north (Around to the east) to a point along the horizon under a celestial objecy
Declination
An angular measure of the distance of a star north or south of the celestial equator
Diurnal motion
-the rotation of the Earth
-Causes the nightly motion of the stars
(rise in the East and set in the West)
Right ascension
A measurement of a stars position measured along the celestial equator starting at the Vernal Equinox. Measured in a unit of time
On a given night we see different stars at different times of the night. 6 months later we see a different set of stars during the night - why?
- Stars change on a given night due to the rotation of the earth on its axis
- after 6 months the stars change due to the orbit of the earth
The Old Testament talks about the north star..is it referring to Polaris?
This would not be reference to Polaris bc the earth wobbles in precession, causing the position of the stars to change in the night sky. (Changes slowly over 26,000 years) The position of the North Celestial Pole has changed over time and pointed to other stars besides Polaris.
Celestial sphere
N and S Celestial poles and Equator are extensions of Earth’s poles and Equator
Constellations
Latin ‘group of stars’
- used to define regions of the sky and to tell the seasons
- 88 constellations
Astronomy as navigation (2 systems)
Many observatories established to monitor the positions of stars so they could be used for navigation
- also used to establish local time and local start to the longitude system
- height of N star s important to navigation
2 systems to give positions of the stars
- Altitude/Azimuth
- Right ascension/declination
Altitude and Azimuth
Altitude - the height above the horizon
Azimuth - an angle measured from N around to the E
-in this system: measure to right below the star in azimuth and then measure up to get the altitude
(PROBLEM bc stars position changes as earth rotates)
Right ascension and declination
(Uses poles and equator)
Right Ascension
-longitude like measure
-measured about the Celestial Equator (in units of hour, min, sec
-0 point is at the vernal equinox - then measure around the equator to the east
Declination
- latitude like measure
- measure angle above or below the Celestial Equator
- measured in degrees, min, sec
- Celestial Poles are at 90 degrees N or S (+ or -)
“Precession of the Equinox”
Earth wobbles over time
- changes the direction of the pole and therefore the position of the equinox and the N star
- causes the celestial poles and equator to slowly change positions
Where is Universal Time for astronomy
Greenwich, England
-also the location of the Prime Meridian, or starting point of the system
Before time zones how was 12:00 pm defined in a given city?
The time when the Sun was due south (on the meridian)
How long does it take for the Earth to make one complete rotation on its axis
23 h 56 m of SOLAR time
For western world, what calendar do we use?
The Gregorian calendar
Took a trip to Anchorage, Alaska where latitude is 61.2 degrees N. Where would we expect to find Polaris in the sky?
Lower in the sky than in provo (40 degrees N)
How long does it take the earth to make one full orbit of the Sun
365.2564 days
A given star rises above the horizon at 12 midnight on a given day. When will that same star rise 10 days later?
40 min earlier (11:20 pm)
T/F the hottest day of the year occurs when the sun reaches its highest pt in the sky
FALSE
- In provo the sun reaches highest pt on June 21
- hottest temp are in July and August
- other factors that just directness of sun light
Another planet almost exactly like earth in another solar system. It is orbiting at the same distance from its star as the earth from the sun. - however it rotates on its axis twice as fast as earth. How would this effect solar and sidereal days for this planet?
- Sidereal days would be half as long
- length of true days is harder bc it wouldn’t move as far in its orbit before it went back to lining up with the Sun. In the end the solar day might be a little under 2 min different than the sidereal day
What are the major factors that contribute to temperature in a given season?
-the input of Solar energy to the system (peaks near end of June) & heat capacity system (something hot takes time to cool off)
how direct the sunlight hits the earth and the amount of time the sun is above the horizon. In the summer months, the sun rises higher in the sky, meaning the sun is more direct in the sunlight it projects to a specific area. Whereas in the winter months, the sun is lower in the sky and projects heat at an angle, spread out across the land. Also in the summer months, the sun remains above the horizon for a longer period of time which makes the days longer and warmer. However, the earth stores energy, so although the sun is highest in the sky on June 21st, it is not the hottest day of the year
Use constellations to orient ourselves in the sky
Provo’s latitude is 40 degrees north
- Polaris is currently near N celestial pole
- therefore Polaris is 40 degrees above the horizon
- can always know your latitude in N hemisphere by knowing where Polaris is
Altitude of Polaris?
- altitude of NCP = the latitude
- latitude of NCP is 90 degrees so the altitude is 90 degrees
In Provo (latitude approximately 40 degrees North) if i look due south, what is the altitude of the celestial equator?
- celestial equator is 90 degrees from NCP
- there are 180 degrees from N to S
- the celestial equator is 50 degrees above due south
Constellations also tell you…
The time of year by looking to the east around the time of sunset
Why seasons?
(2: directness of the sunlight and the time the sun is above the horizon)
Due to the earth’s tip
-in the summer the sun is higher in the sky and the light is more direct (also up longer)
-in the winter the sun is lower in the sky and the light is more spread out
Seasons ARE different in N and S hemispheres
-NOT CAUSED by the distance of the sun
Solar time
Time we read off our watches - partially based off the Sun
-12pm is when the sun is due south each day (this is local time)
-in SOLAR TIME one day - 24 hrs
(BUT earth actually rotates once on its axis in 23 h 56 m of solar time)
Time zones
Time problems really seen in the development of railroad (up to 1875)
- railroads ran on the time of their home city
- Time Zones (we are Mountain time)
Sidereal time (Star time)
-bc earth is also moving on its orbit around the sun
The time it takes the stars to go from due south to due south is 23 h 56m of Solar time
-we define one full rotation of the earth as 24h of what we call Sidereal Time (Star time)
Local Sidereal time - the right ascension of the stars which are on the meridian
If one night a sidereal and solar clock match exactly - how much off one night later?
one night
-4 min (each day is 4 min off)
One month (30 days) -120 min (2 hours)
6 months
-720 min (12 hours)
1 year
-24 hours off (but actually match again)
Sidereal Year
- 2564 days
- best way to calc a year but not used bc not convenient
Tropical Year
Julius Caesar wanted spring to always be Mar. 21, but bc of precession the equinox slowly moves and changes beginning of spring (CAUSED TO MOVE AWAY FROM LUNAR CALENDARS)
-tropical year (365.2422 days) used to keep spring on same date
Caesar assumed 365.25 days
-off by 11m14s tropical
-off by 9m13s sidereal
-by 16th century it was off by 10 days (Spring started Mar. 11)
Bad for Roman Catholic church bc Easter kept coming earlier
Pope Gregory XIII
Roman Catholic problem with Caesar’s calendar bc spring kept coming earlier and therefore easter
- Pope Gregory XIII reformed the calendar in 1582 A.D.
- started by dropping 10 days out of 1582 (Oct. 4 was followed by Oct. 15)
Papal Decree
- leap year modified to be every 4 years
- except the end of a century which must be divisible by 400 (1900 wasn’t, but 2000 was)
- this is our current system called the GREGORIAN CALENDAR
Astronomy calendars
elimate the year (time is expressed in terms of days)
-Julian Date (JD) - the # of days since a fixed date in the past, plus a fraction of a day
-Julian Date is based on the # of days that have elapsed since Jan. 1 4713 BC at noon in Greenwich
(Based on Universal Time - but starting at noon)
JD right now = 2456905.208
What time of day should you expect to easily see a waxing crescent moon?
During sunset
During the waning gibbous phase, how much of the entire Moon’s surface is illuminated by the sun?
1/2
During a total lunar eclipse what would be the phase of the moon
full moon
How long does it take the moon to orbit the Earth?
27.3 days
T/F We can see the entire surface of the moon from the earth
FALSE
Why does the moon go through phases?
Half the moon is always lit by the sun. Because the moon orbits the Earth, those on the earth will see a different portion of the lit side of the moon
Why is the area of the earth that can see a lunar eclipse much larger than the area that can see a solar eclipse
Lunar eclipse = when earth casts a shadow on the moon
Solar eclipse = when moon casts a shadow on the earth
-bc earth is bigger and casts a larger shadow than the moon does
Suppose moon was on its current orbit and all characteristics are same, except the moon was only 3/4 of its current radius.
-what would be the impact on its phases and on eclipses
- No change in phases or the orbit of the moon.
- The moon wouldn’t be large enough to block the entire disk of the sun so no total solar eclipse, only annular
- lunar eclipses would be longer
Moon phases (Lunar phases)
-we see moon bc of reflected sunlight - the moon is illuminated by the sun just like earth (half the moon is in shadow and half in light)
- New moon (when moon is btwn the earth and the sun, the dark half is facing earth)
- Full moon (earth is in middle we only see lit half)
btwn new and full -waxing crescent -1st quarter -waxing gibbous btwn full and new -waning gibbous -3rd quarter -waning crescent
*biblical new moon is actually a very thin waxing crescent moon - the first moon that can be seen in the night sky at sunset
Faces if the moon
The same features are always facing us on earth
-therefore the rotation of the moon occurs at the same rate as the revolution of the moon and earth
Earthshine - the part of the moon that isn’t illuminated by the sun (looks like a shadow)
-not a shadow but reflected light - light being reflected off the earth that is being reflected by the moon
Two types of months in astronomy
Sidereal month
- the time it takes the moon to be in the same position with respect to the background stars
- one true orbit (27.3 days)
Synodic (lunar) month
- period from new moon to new moon
- also the length of a day on the moon (29.53)
