What is the history of our solar system?

Contributed by:
kevin
Planetary exploration missions are conducted by some of the most sophisticated robots ever built. Through them, we extend our senses to the farthest reaches of the solar system and into remote and hostile environments, where the secrets of our origins and destiny lie hidden.
1. Lecture 8
Our Solar System
Jiong Qiu, MSU Physics Department
The Cassini
2. Guiding Questions
1. Are all the other planets similar to Earth, or are they very
different?
2. Do other planets have moons like Earth’s Moon?
3. How do astronomers know what the other planets are
made of?
4. Are all the planets made of basically the same material?
5. What is the difference between an asteroid and a comet?
6. What determines whether a planet or satellite can retain
a certain gas in its atmosphere?
7. Why do interplanetary spacecraft carry devices for
measuring magnetic fields?
3. Current, Future, and Past Solar System Missions
Planetary exploration missions are conducted by some
of the most sophisticated robots ever built. Through them
we extend our senses to the farthest reaches of the solar
system and into remote and hostile environments, where
the secrets of our origins and destiny lie hidden. The
coming years of solar system exploration promise to be
the most exciting and productive yet, as we explore
entirely new worlds and probe in even greater detail the
fascinating environments we have discovered.
4. We will learn the motion, structure, atmosphere,
magnetic field of the Sun, planets, and satellites,
and how to observe them.
We will learn how to explain them -- gravity,
energy, and nature of light.
We will learn why our planet, the Earth, hosts
5. Solar System
Mercury, Venus, Earth, Mars, Jupiter, Saturn, Uranus, Neptune, (Pluto).
(MVEMJSUN – My Very Easy Method Just Seems No Use)
q The star we call the Sun and all the celestial bodies that orbit
the Sun
n including Earth and other seven planets
n all their various moons
n smaller bodies such as asteroids, comets, meteoroids and dust
6. 8.1 Planets
According to their orbits,
planets fall into two classes:
the inner planets (Mercury,
Venus, Earth, and Mars) are
Earthlike, and the outer
planets (Jupiter, Saturn,
Uranus, and Neptune) are
Jupiter like.
7. the terrestrial (inner) planets
The four inner planets are called terrestrial planets
– Relatively small: Earth is the largest
– Low mass: Earth is the heaviest
– High densities (4000 to 5500 kg/m3) with iron cores
– Composed primarily of rocky materials with solid
surface
8. the Jovian (outer) planets
The four gas giant outer planets are called Jovian planets
– Large diameters (4 to 11 times Earth’s size)
– High mass (14 to 318 times Earth’s mass)
– Low average densities (700 to 1700 kg/m3)
– Composed primarily of hydrogen and helium without a
solid surface
Jupiter is the largest and the most massive!
9. Pluto – special case: no longer a planet!
Pluto is a special case
– Smaller than
any of the
terrestrial
planets
– Intermediate
average density
of about 1900
kg/m3
– Its density
suggests it is
composed of a
mixture of ice
and rock Distance and size, drawn to scale.
10. Q: how do we know the composition of planets?
The average density gives a rough idea of the composition
of a planet.
ρ = density, M = mass of the object
M M V = volume of the object
ρ= =
V 4
πR 3 = 4 π R3 / 3 (for spheres)
3 R = radius of the spherical object
• Average density of water: ρwater = 1000 kg/m3
• Average density of metal: ρmetal = 13,000 kg/m3
• Average density of rock: ρrock = 3000 kg/m3
The terrestrial planets (ρ = 4000-5500 kg/m3) are made of
rocky materials and have dense iron cores.
The Jovian planets (ρ = 700-1700 kg/m3) are composed
primarily of light elements such as hydrogen and helium.
11. 8.2 satellites, asteroids, and comets
Earth’s
diameter
is 12,800
kilometer,
twice that
of Titan.
- All the planets except Mercury and Venus have satellites.
- More than 130 satellites are known. Jupiter has more than 60.
- Seven large satellites are almost as big as the terrestrial planets.
• Comparable in size to the planet Mercury
- Ganymede and Titan are the largest; Titan has an atmosphere.
• The remaining satellites of the solar system are much smaller
12. Asteroids are small rocky objects, orbiting the Sun at
distances of 2 to 3.5 AU in `the asteroid belt’, between
Mars and Jupiter.
Asteroids
in the
distance
by HST.
(R. Evans, &
K.Stapelfeldt
JPL)
Hubble Space Telescope
observed rotation of the mini
planet Ceres, the largest
asteroid (diameter = 900 km)
in the asteroid belt. Water may
exist beneath its surface. Asteroid 433 Eros
13. - Comets and other Kuiper belt objects are made of dirty ice.
- The Kuiper belt extends far beyond the orbit of Neptune.
- Pluto is the largest member of the Kuiper belt.
Comet Hale-Bopp
o Both ateroids and comets
are remnants left over from
the formation of the
planets.
o They all orbit around the
Sun, following Kepler’s
Comet Halley
laws.
o Like the two categories of
planets, asteroids are more
“terrestrial”, comets are
“Jovian”.
Copyright of the UK Schmidt
14. asteroid belts
Kuiper belt and
Oort cloud
15. Q: What’s the difference between planets,
satellites, asteroids, and comets?
1. Satellites orbit around planets, planets orbit the Sun.
2. Asteroids and comets also orbit the Sun, but
they are not large enough to become planets.
3. Asteroids locate in the asteroid belt between
Mars and Jupiter. Comets are in Kuiper belt
beyond Neptune.
4. Comets are likely extra-solar system objects!
16. 8.3 Orbits of Planets - Kepler’s laws
• Most planets orbit the Sun in
the same direction and in almost
the same plane: ecliptic is the
plane of the Earth’s orbit.
• Most planets have nearly
circular orbits - the eccentricity
of the orbit is very small. (from Arizona State U.)
• The farther away from the Sun,
the longer the orbital period:
Kepler’s third law: P2 = a3
(P = sideral period, in year, a = semimajor axis of orbit, in AU)
Ex.1 Saturn’s distance to the Sun is about 10 AU. A year
on Saturn is as long as how many Earth year?
17. Newton/Kepler’s law determines the planet mass
Newton’s Law of Universal Gravitation accounts for
Kepler’s laws and explains the motions of a binary system.
mM
FG = G 2
r
F = gravitational force between two objects (in newtons)
m = mass of the planet (in kilograms)
M = mass of the Sun (in kilograms)
r = distance between planet and Sun (in meters)

G = 6.67 × 10–11 newton • m2/kg2 , universal constant of
gravitation
18. Newton’s form of Kepler’s third law
The gravitational (pull or Newton demonstrated that
attractive) force keeps the
planets orbiting the Sun. Kepler’s third law follows
logically the law of gravity,
2
2 4 π mr and can be re-written as:
F = mω r = 2
= FG
P 3
# GM & 2
a = % 2 (P
$ 4π '
P = sidereal period, in seconds
a = semimajor axis, in meters
M = mass of the Sun, in kg
G = universal constant of gravitation
€ = 6.67 x 10-11
This same relation is used to describe a satellite orbiting a planet.
19. P2 = a3
The further away from the sun, the longer it takes to finish one
orbit. Kepler’s law also applies to asteroids and comets, all
solar system objects that orbit the Sun.
Newton’s law of the universal gravitation accounts
for Kepler’s laws.
20. Newton’s form of Kepler’s third law
The gravitational (pull or Newton demonstrated that
attractive) force keeps the
planets orbiting the Sun. Kepler’s third law follows
logically the law of gravity,
2
2 4 π mr and can be re-written as:
F = mω r = 2
= FG
P 3
# GM & 2
a = % 2 (P
$ 4π '
P = sidereal period, in seconds
a = semimajor axis, in meters
M = mass of the Sun, in kg
G = universal constant of gravitation
€ = 6.67 x 10-11
Scaling the equation to Sun-Earth system: Kepler’s third law.
21. 8.4 The atmosphere is retained by gravity
Whether gases can stay in a planet’s atmosphere depends on
the combination of the following three factors:
o planet’s mass and size: gravity can retain gas particles.
o gas composition: light gases run faster than heavy gases.
o temperature: gases at higher temperature run faster.
When an object has a high enough speed, it can escape from
the planet’s gravity (think about how we launch a rocket). The
escape speed is:
(see Box 7.2 for
2GM escape speed at
v esc =
R each planet)
M = mass of the planet(kg); R = radius of the planet(m);
G = gravitational constant = 6.67 x 10-11 N m2/kg2.
22. The average speed of a gas at a temperature is given as:
1/ 2
" 3kT %
v th = $ ' (thermal speed)
m = gas mass(kg);
# m &
T = temperature (K=kelvins);
vth = speed (m/sec);
k = Boltzmann constant = 1.38 x 10-23 J/K

(optional) Maxwellian distribution of particles in thermal
A good thumb rule goes:
If 6 vth > vesc , the particles (atoms or molecules) escape.
If 6 vth < vesc , the particles (atoms or molecules) stay!
23. 1/ 2
" 3kT % 2GM
6v th = 6$ ' ⇔ v esc =
# m & R
Higher temperature, less likely to retain a gas.
Gas particles with smaller mass (m), less likely to be retained.
€ Planet of larger mass (M), more likely to retain a gas.
Q: among 8 planets, 1 does not have appreciable
atmosphere. Which one and why?
Terrestrial planets: high temperature, weak gravity, so low
mass gases escape and massive gases stay.
Jovian planets: low temperature, strong gravity, can retain
even very light gases, e.g., hydrogen and helium.
Gravity and distance to the Sun are crucial!
24. 1 GMm
escape temperature: T esc >
54 kR
Ex 2: compare the abilities of Earth and the Moon to retain
molecular oxygen (O2) gas in the atmosphere. (see Box-7.2)

We may calculate the escape temperature for molecular
oxygen on Earth and on the Moon. For Earth, Tesc = 4500
K, much greater than Earth’s mean temperature. And for
the Moon, Tesc = 200 K, smaller than the Moon’s mean
temperature. Therefore, molecular oxygen gas is retained
on Earth but not on the Moon.
Q: among 7 largest satellites in the solar system,
Titan is the only one with an appreciable
atmosphere. Why is that?
25. 8.5 Composition
The average density gives a rough idea of the composition
of a planet.
ρ = density, M = mass of the object
M M V = volume of the object
ρ= =
V 4
πR 3 = 4 π R3 / 3 (for spheres)
3 R = radius of the spherical object
• Average density of water: ρwater = 1000 kg/m3
• Average density of metal: ρmetal = 13,000 kg/m3
• Average density of rock: ρrock = 3000 kg/m3
The terrestrial planets (ρ = 4000-5500 kg/m3) are made of
rocky materials and have dense iron cores.
The Jovian planets (ρ = 700-1700 kg/m3) are composed
primarily of light elements such as hydrogen and helium.
26. Spectroscopy more accurately reveals the chemical
composition of surface and atmosphere of planets.
• The spectrum of a planet or satellite with an atmosphere
reveals the atmosphere’s composition.
• If there is no atmosphere, the spectrum indicates the
composition of the surface.
• The substances that make up the planets can be
classified as gases, ices, or rock, depending on the
temperatures at which they solidify.
• The terrestrial planets are composed primarily of rocky
materials, whereas the Jovian planets are composed
largely of gas.
27. Atmosphere composition
Ex 3: Atmosphere of Titan – Methane is dominant
Absorption features reveal the atmosphere composition.
The amount of absorption depends on the abundance of the
elements and temperature and density of the atmosphere.
28. Formation of Titan Spectra
29. Ex.4 Moonshine and earthshine spectra reflecting
atmosphere properties
Atmosphere molecular line:
Solar line: H-alpha line
oxygen A bands
30. Ex.5: Additional sodium absorption found in the
spectroscopy data of the planet transit shows evidence of
HD 209548b having an atmosphere. Credit: SpaceRef.com
31. Surface Composition
Ex 6: Surface of Europa - Ice dominated
A solid surface,
unlike an
atmosphere,
does not
produce sharp
spectral lines.
The broad absorption and reflection spectrum of
Jupiter’s moon Europa compared with ice.
32. Hydrogen and helium are abundant on the Jovian
planets, whereas the terrestrial planets are
composed mostly of heavy element.
Mars
Jupiter
Surface composition
33. 8.6 Cratering and age
Cratering on planets and satellites is the result of impacts
from interplanetary debris
o When an asteroid, comet, or meteoroid collides with the surface
of a terrestrial planet or satellite, the result is an impact crater.
o Geologic activity renews the surface and erases craters, so a
terrestrial world with extensive cratering has an old surface and
little or no geologic activity.
Craters on Moon, Earth, and Mars.
34. 8.7 Magnetic fields
A planet with a magnetic field indicates a fluid interior in motion.
• Planetary magnetic fields
are produced by the motion
of electrically conducting
liquids inside the planet.
• This mechanism is called a
dynamo.
• If a planet has no magnetic
field, that is evidence that
there is little such liquid
material in the planet’s
interior or that the liquid is
not in a state of motion.
The magnetic fields of a
bar magnet.
35. • The magnetic fields of
terrestrial planets are
produced by metals such as
iron in the liquid state.
• Mercury and Earth have
global magnetic field.
• Mars has magnetized
regions.
Mars
• Magnetic field is not found in
Venus, maybe due to its slow
rotation.
36. Jupiter’s strong
magnetic field
interacting with
solar wind.
(NASA)
• The stronger fields of the Jovian planets are generated by
liquid metallic hydrogen (Jupiter & Saturn) or by water with
ionized molecules dissolved in it (Uranus and Neptune).
• Jupiter, Saturn, Uranus and Neptune all have global
magnetic field.
• Jupiter has the strongest magnetic field among all planets.
37. How to determine properties of the planets?
• orbit period: direct observation
• distance: parallax, Kepler’s third law
• diameter: direct observation of angular size, and small-
angle formula
• mass: Newton’s form of Kepler’s third law
• density: mass/volume
• chemical composition: density, spectroscopic
observation (can diagnose atmosphere and surface
composition)
• magnetic fields: magnetometer observation, radio
observation
• internal structure: inferred from craters, magnetic fields,
quakes
38. Gravity and distance to the Sun are the keys
to understanding the solar system
rotation
composition
distance temperature state of matter magnetic field
mass/size surface
orbit period atmosphere
internal heat geological
activity
Q: Where does GRAVITY spell out?
Our knowledge of the Universe critically
depends on how much we understand LIGHT.
39. Key Words
• asteroid • kinetic energy
• asteroid belt • Kuiper belt
• average density • Kuiper belt objects
• chemical composition • liquid metallic hydrogen
• comet
• magnetometer
• dynamo
• meteoroid
• escape speed
• minor planet
• ices
• impact crater • molecule
• Jovian planet • spectroscopy
• terrestrial planet
40. summary
• Planets are categorized as terrestrial and Jovian planets.
The terrestrial planets are small inner planets, and Jovian
planets are large outer planets.
• The terrestrial planets are rocky, dense, made of heavy
elements, and the Jovian planets are gaseous and made of
hydrogen, helium or ice.
• All planets but Mercury and Venus have satellites.
• Asteroids and comets are small objects orbiting around the
Sun in asteroids belt (between Mars and Jupiter) or Kuiper
belt. Asteroids are “terrestrial” and comets are “Jovian”.
• Whether a planet has a certain gas in the atmosphere
depends on the temperature and gravity on the planet and
the mass of the gas, which determine whether the gas can
escape.
• Presence of magnetic fields reflects motion of electrically
conducting liquids inside the planets.