Transcript here
ASTRO 101
Principles of Astronomy
Instructor: Jerome A. Orosz
(rhymes with “boris”)
Contact:
• Telephone: 594-7118
• E-mail: [email protected]
• WWW:
http://mintaka.sdsu.edu/faculty/orosz/web/
• Office: Physics 241, hours T TH 3:30-5:00
Text:
“Discovering the Essential Universe,
Fifth Edition”
by
Neil F. Comins
Course WWW Page
http://mintaka.sdsu.edu/faculty/orosz/web/ast101_fall2012.html
Note the underline: … ast101_fall2012.html …
Also check out Nick Strobel’s Astronomy Notes:
http://www.astronomynotes.com/
No appointment needed!
Just drop by!
Where: Room 215, physics-astronomy building.
When:
• Monday:
• Tuesday:
• Wednesday:
• Thursday:
12-2, 4-6 PM
12-1 PM; 4-6 PM
12-2, 5-6 PM
4-6 PM
Homework/Announcements
• Homework due Tuesday, October 9: Question
5, Chapter 4 (Describe four methods for
discovering exoplanets)
Next:
Comparative Planetology
• Outline and introduction to the Solar System
• Planets around other stars
Quick Concept Review
• Some useful concepts:
– Density
– Albedo
Density and Albedo
• The concepts of density and albedo are
useful in planetary studies.
• Density = mass/volume
– The density of water is 1 gram per cubic cm.
– The density of rock is 3 grams per cubic cm.
– The density of lead is 8 grams per cubic cm.
• The density of an object can give an
indication of its composition.
Density and Albedo
• The concepts of density and albedo are
useful in planetary studies.
• Albedo = % of incident light that is
reflected.
– A perfect mirror has an albedo of 100%
– A black surface has an albedo of 0%.
• The albedo of an object is an indication of
the surface composition.
The Planets
• Why solar system planets are special:
The Planets
• Why solar system planets are special:
Planets are resolved when seen through
telescopes (i.e. you can see the disk, surface
features, etc.).
The Planets
• Why solar system planets are special:
Planets are resolved when seen through
telescopes (i.e. you can see the disk, surface
features, etc.).
You can also send spacecraft to visit them.
The Planets
• Why solar system planets are special:
Planets are resolved when seen through
telescopes (i.e. you can see the disk, surface
features, etc.).
You can also send spacecraft to visit them.
Stars always appear pointlike, even in the
largest telescopes.
The Planets
• Why solar system planets are special:
Planets are resolved when seen through
telescopes (i.e. you can see the disk, surface
features, etc.).
You can also send spacecraft to visit them.
Stars always appear pointlike, even in the
largest telescopes. Also, they are so far away
that we cannot send probes to study them.
The Solar System
• The Solar System refers to the Sun and the
surrounding planets, asteroids, comets, etc.
The Solar System
• The Solar System refers to the Sun and the
surrounding planets, asteroids, comets, etc.
• Do not confuse “solar system” with “galaxy”:
– The solar system is the local collection of planets
around the Sun.
– A galaxy is a vast collection of stars, typically a
hundred thousand light years across.
The Solar System Census:
• There were 5 planets known since antiquity:
–
–
–
–
–
Mercury
Venus
Mars
Jupiter
Saturn
The Solar System Census:
• There were 5 planets known since antiquity:
–
–
–
–
–
Mercury
Venus
Mars
Jupiter
Saturn
• Since the 1600s (Kepler, Galileo, Newton),
the Earth was considered a planet as well.
New Members
• Uranus: discovered in 1781 by William Herschel.
New Members
• Uranus: discovered in 1781 by William Herschel.
• Neptune: discovered in 1846 by Johann Galle
(based on the predictions of John C. Adams and
Urbain Leverrier).
New Members
• Uranus: discovered in 1781 by William Herschel.
• Neptune: discovered in 1846 by Johann Galle
(based on the predictions of John C. Adams and
Urbain Leverrier).
• Pluto: discovered in 1930 by Clyde Tombaugh.
New Members
• Uranus: discovered in 1781 by William Herschel.
• Neptune: discovered in 1846 by Johann Galle
(based on the predictions of John C. Adams and
Urbain Leverrier).
• Pluto: discovered in 1930 by Clyde Tombaugh.
• Asteroids: thousands, starting in 1801.
New Members
• Uranus: discovered in 1781 by William Herschel.
• Neptune: discovered in 1846 by Johann Galle
(based on the predictions of John C. Adams and
Urbain Leverrier).
• Pluto: discovered in 1930 by Clyde Tombaugh.
• Asteroids: thousands, starting in 1801.
• Kuiper Belt Objects: Dozens, starting in the
1980s.
Pluto “Demoted”!
• The definition of a “planet” was changed
recently:
– Planets: The eight worlds from Mercury to
Neptune.
– Dwarf Planets: Pluto and any other round object
that "has not cleared the neighborhood around
its orbit, and is not a satellite."•
– Small Solar System Bodies: All other objects
orbiting the Sun.
http://www.space.com/scienceastronomy/060824_planet_definition.html
The Solar System
• The planets orbit more or less in the same plane in
space. Note the orbit of Pluto.
• This view is a nearly edge-on view.
Classifications of Solar System
Objects
The Solar System
• The Solar System refers to the Sun and the
surrounding planets, asteroids, comets, etc.
• The scale of things:
– It takes light about 11 hours to travel across the Solar
system.
The Solar System
• The Solar System refers to the Sun and the
surrounding planets, asteroids, comets, etc.
• The scale of things:
– It takes light about 11 hours to travel across the Solar
system. This is 0.001265 years.
The Solar System
• The Solar System refers to the Sun and the
surrounding planets, asteroids, comets, etc.
• The scale of things:
– It takes light about 11 hours to travel across the Solar
system. This is 0.001265 years.
– It takes light about 4.3 years to travel from the Sun to
the nearest star.
The Solar System
• The Solar System refers to the Sun and the
surrounding planets, asteroids, comets, etc.
• The scale of things:
– It takes light about 11 hours to travel across the Solar
system. This is 0.001265 years.
– It takes light about 4.3 years to travel from the Sun to
the nearest star.
– It takes light about 25,000 years to travel from the
Sun to the center of the Galaxy.
Scale Model Solar System
• Most illustrations of the
solar system are not to
scale.
Scale Model Solar System
• Most illustrations of the
solar system are not to
scale.
• Usually, the size of the
planets shown is too large.
Scale Model Solar System
• Build your own scale model of the solar
system:
http://www.exploratorium.edu/ronh/solar_system/
http://pages.umpi.edu/~nmms/solar/
Scale Model Solar System
• Build your own scale model of the solar
system:
http://www.exploratorium.edu/ronh/solar_system/
http://www.umpi.maine.edu/info/nmms/solar/index.htm
• Conclusion: the solar system is pretty
empty.
Scale Model Solar System
• Most depictions of asteroids in the movies
are wrong…
The Scale Model Solar System
• Most depictions of asteroid fields are also not to
scale. Image from Star Trek Voyager.
Two Types of Planets
• Planets come in two
types:
– Small and rocky.
– Large and gaseous.
Or
– Terrestrial
– Jovian
The Terrestrial Planets
• The terrestrial planets are
Mercury, Venus, Earth
(and Moon), and Mars.
• Their densities range
from about 3 grams/cc to
5.5 grams/cc, indicating
their composition is a
combination of metals
and rocky material.
The Terrestrial Planets
• The terrestrial planets are Mercury, Venus, Earth (and Moon), and Mars.
The Giant Planets
• The giant planets are Jupiter, Saturn, Uranus, and
Neptune.
The Giant Planets
• The radii are between about 4 and 11 times
that of Earth.
• The masses are between 14 and 318 times
that of Earth.
The Giant Planets
• The radii are between about 4 and 11 times
that of Earth.
• The masses are between 14 and 318 times
that of Earth.
• However, the densities are between 0.7 and
1.8 grams/cc, and the albedos are high.
The Giant Planets
• The radii are between about 4 and 11 times
that of Earth.
• The masses are between 14 and 318 times
that of Earth.
• However, the densities are between 0.7 and
1.8 grams/cc, and the albedos are high.
• The planets are composed of light elements,
mostly hydrogen and helium.
The Gas Giants
• The composition of the giant planets,
especially Jupiter, is close to that of the Sun.
• The internal structures of these planets is
completely different from that of the Earth.
In particular, there is no hard surface.
• These planets are relatively far from the Sun
(more than 5 times the Earth-Sun distance),
so heating by the Sun is not a big factor.
Next:
• The formation of the Solar System
Star Formation
• The starting point is a giant molecular cloud.
The gas is relatively dense and cool, and usually
contains dust.
• A typical cloud is several light years across, and
can contain up to one million solar masses of
material.
• Thousands of clouds are known.
Side Bar: Observing Clouds
• Ways to see gas:
By “reflection” of a nearby light source. Blue light
reflects better than red light, so “reflection nebulae”
tend to look blue.
By “emission” at discrete wavelengths. A common
example is emission in the Balmer-alpha line of
hydrogen, which appears red.
Side Bar: Observing Clouds
• Ways to see dust:
If the dust is “warm” (a few hundred degrees K)
then it will emit light in the long-wavelength
infrared region or in the short-wavelength radio.
Dust will absorb light: blue visible light is highly
absorbed; red visible light is less absorbed, and
infrared light suffers from relatively little
absorption. Dust causes “reddening”.
Giant Molecular Clouds
• This nebula is in the belt of Orion. Dark dust lanes
and also glowing gas are evident.
Giant Molecular Clouds
• Interstellar
dust makes
stars appear
redder.
Giant Molecular Clouds
• This images
shows dust
obscuration, an
emission nebula,
and a reflection
nebula.
Giant Molecular Clouds
• Inside many
nebula one finds
very dense cores
called Bok
globules that are
ready to
collapse…
Gravity and Angular Momentum
• There are two important concepts to keep in
mind when considering the fate of giant
molecular clouds:
– Gravity: pulls things together
– Angular momentum: a measure of the spin of
an object or a collection of objects.
Gravity
• There are giant clouds of gas and dust in the
galaxy. They are roughly in equilibrium,
where gas pressure balances gravity.
Gravity
• There are giant clouds of gas and dust in the
galaxy. They are roughly in equilibrium,
where gas pressure balances gravity.
• Sometimes, an external disturbance can
cause parts of the cloud to move closer
together. In this case, the gravitational
force may be stronger than the pressure
force.
Gravity
• Sometimes, an external disturbance can
cause parts of the cloud to move closer
together. In this case, the gravitational
force may be stronger than the pressure
force.
• As more matter is pulled in, the
gravitational force increases, resulting in a
runaway collapse.
Angular Momentum
• Angular momentum is a measure of the spin
of an object. It depends on the mass that is
spinning, on the distance from the rotation
axis, and on the rate of spin.
• I = (mass).(radius).(spin rate)
• The angular momentum in a system stays
fixed, unless acted on by an outside force.
Conservation of Angular Momentum
• An ice skater demonstrates
the conservation of angular
momentum:
Conservation of Angular Momentum
• An ice skater demonstrates
the conservation of angular
momentum:
• Arms held in: high rate of
spin.
• Arms extended: low rate of
spin.
• I = (mass).(radius).(spin rate)
(angular momentum and
mass are fixed here)
Conservation of Angular Momentum
• If an interstellar cloud has some net
rotation, then it cannot collapse to a point.
Conservation of Angular Momentum
• If an interstellar cloud has some net
rotation, then it cannot collapse to a point.
Instead, the cloud collapses into a disk that
is perpendicular to the rotation axis.
Coming up:
• Chapter 5 (The Earth)
• Chapter 6 (Other Planets and Moons)