The Science of Astronomy - Ohio Wesleyan University

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Transcript The Science of Astronomy - Ohio Wesleyan University

The Science of Astronomy
• Astronomy involves the study of celestial objects
and their interactions
• It is a science much like biology, chemistry, and
physics
– Observations and measurements are made of objects
and phenomena
– Theoretical models are constructed in order to explain
the observations
– Comparisons are made between the theoretical models
and the observations
– Modifications are made to the theoretical models in order
to better explain the observations
• There are both observational (experimental) and
theoretical astronomers/astrophysicists
The Science of Astronomy
• Sometimes, the models used are relatively simple
– Gravity is well understood and is used to explain the orbits
of planets as well as spacecraft trajectories
• Other times, the models require some
approximations and simplifications
– When there are many objects interacting with one another
– When there are lots of different effects happening at the
same time
• Sunspots
• Star and planet formation
• Like other sciences, astronomy has advanced with
progress in technology (like the Hubble Space
Telescope) and computing power
Image courtesy of ANL
and NASA
The Evening Sky
• We’ll focus on the universe that is “close to home”,
namely our Solar System
• First we’ll try to understand how the sky “works”
– How do astronomers specify locations on the sky?
– Why do the Sun, Moon, planets, and stars appear to
move the way they do in the sky?
– Why are there phases of the Moon?
• Since observation is such an important part of
astronomy, we’ll start with a good old fashioned
stargazing session on a clear evening (no special
equipment necessary!)
• Where celestial objects are in the sky depend on
the time and the location
The Evening Sky
• Several distinctive patterns of stars appear (constellations)
• The following observations appear consistently:
– Looking northward, the familiar Big Dipper is seen
– The two stars that form the “ladle”, furthest from the “handle”, form a
line that points toward the star Polaris (the “North Star”)
– Facing Polaris means facing due North
– The stars, planets, and Moon appear to move westward during the
night (the motion can be detected within about a minute of
observation)
– Polaris’ position appears fixed
– There is a circumpolar zone of stars centered near Polaris that
always remain above the horizon and appear to rotate
counterclockwise about Polaris
– Stars not located in the circumpolar zone move on circles that carry
them below the horizon (size of circumpolar zone depends on
location)
Coordinate Systems
• While observing, it is helpful to have a definitive
system for locating objects
• Astronomers use several ways of locating objects in
the sky
• Locations are typically identified by using a
coordinate system
– Coordinates are a set of numbers that pinpoint a location
– For example, house address “200 1st Ave.” combines a
pair of numbers (200,1) to locate a house
– A point in a 2–D space can be located with a coordinate
system having two axes:
y
For the system to work, there
(x1,y1)
must be an origin (zero point)
(0,0)
x
Terrestrial Coordinate System
• The most commonly used terrestrial coordinate
system (for locating places on Earth) uses an origin
located on the Earth’s equator
– The coordinates consist of latitude (angle between
equator and geographical location) and longitude (angle,
east or west, around the equator to point nearest to
location)
– The equator is an example of a great circle: a circle that
divides a sphere into 2 equal parts (northern and southern
hemisphere in this case)
– For historical reasons, the exact location of the origin on
the equator is due south of the former location of the
Royal Observatory in Greenwich, England
– The longitude line passing through Greenwich is called
the prime meridian (or Greenwich meridian)
Terrestrial Coordinate System
Celestial Sphere
• We would like to develop a similar coordinate
system for the sky, since it appears to form the
inside of a sphere from our vantage point on Earth
– “Celestial sphere”
• It’s an incorrect description, because the distances
of celestial bodies vary enormously, but it is
convenient way to describe celestial locations
• The celestial sphere has a visible and invisible
hemisphere from our vantage point
– We see only the hemisphere above our horizon
Celestial sphere
(http://csep10.phys.utk.edu/astr161/lect/celestial.html)
Angles
• To measure distances on the imaginary celestial
sphere, we use angular separations
– Most common unit of measure: the degree
– One degree = 1/360 of a full circle
– Smaller units exist for finer measurements
• One minute of arc = 1/60 of a degree
• One second of arc = 1/60 of a minute of arc (equal to angular
diameter of ball in tip of ballpoint pen at a distance of 100 yards!)
• You can use your hands to make approximate angle
measurements – at arm’s length:
– Your finger is about 2° across
– Your fist is about 10° across the knuckles
– Your outstretched hand is about 20° across from the tip of
the thumb to the tip of the little finger
Angular Sizes of Some Celestial Objects
• Constellations: few degrees to few tens of degrees
– Big Dipper is about 20° (2 fists) across
• Sun: about 0.5°
• Moon: about 0.5°
– Important implications of the near equality of Sun and
Moon angular sizes
• Stars: all less than 1 sec of arc
• The bowl of the Big Dipper is about 30° from Polaris
• Any object directly overhead is 90° above the
horizon
• Any object “half-way up” in the sky is 45° above the
horizon
The Horizon System
• A good coordinate system to locate objects from a
single location is the horizon system
• It measures locations relative to the celestial
horizon, a great circle located 900 from the point on
the celestial sphere directly over your head (zenith)
(http://csep10.phys.utk.edu/astr161/lect/celestial.html)
Celestial horizon
(bisects celestial
sphere)
– Be careful to distinguish between “horizon” (the irregular
line marking the meeting of sky and Earth) and “celestial
horizon” (which can only be seen at sea or middle of vast
plain)
The Horizon System
• The two coordinates of the horizon system are
altitude and azimuth
– Altitude = angular distance above the celestial horizon
(corresponds to latitude in terrestrial coordinate system)
• Altitude of horizon = 0°, altitude of zenith = 90°
– Azimuth = angular distance measured eastward from
north, around the celestial horizon, to the point directly
below the chosen point on the celestial sphere
(corresponds to longitude in terrestrial
coordinate system)
• Azimuth of East = 90°, South = 180°,
West = 270°
– Coordinates depend on time and
location of observation
Apparent Rotation of Celestial Sphere
• We’ve already seen that the stars in the circumpolar
region never set but move on circles centered near
Polaris
• Beyond the circumpolar region, the motions of stars
carry them below the horizon
• For an observer in the Northern Hemisphere, stars
in the extreme southern part of the celestial sphere
are never carried above the horizon
– This also means that observers in the Southern
Hemisphere would never see stars in the extreme
northern part of the celestial sphere, like those in the Big
Dipper