Section 14

Question 1

What are the Jovian planets huge gaseous atmospheres made up of?

Answer 1

Hydrogen and helium

Question 2

What is Pluto and how is it believed to have formed?

Answer 2

It is a planetesimal

Remnant from the planet-building phase of Solar System’s early history (from Kuiper belt)

Question 3

What makes the inner terrestrial planets different from the Jovian planets?

Answer 3

They are smaller

They have rock surfaces surrounded by relatively thin atmospheres

More dense

Different internal structures

Question 4

What do all Jovian planets have?

Answer 4

Rings (circumplanetary belts) however they do not reflect light as effectively as Saturn

Question 5

What is the inner structure of Jupiter and Saturn?

Answer 5

Rock and ice core surrounded by metallic hydrogen and molecular hydrogen

Question 6

What is the inner structure of Uranus and Neptune and what gives them their blue colour?

Answer 6

Rock and ice core surrounded by heavier elements: mantle (water, ammonia, methane ices) and hydrogen, helium and methane gas

Methane and ammonia

Question 7

Why do some of the planets have a metallic hydrogen core?

Answer 7

Pressure is so high in core that there are free electrons in core

Question 8

Where do asteroids orbit?

Answer 8

In Asteroid belt; 2 -3.5 AU from the Sun

Question 9

Where do short-period comets orbit?

Answer 9

In Kuiper belt; beyond Neptune (> 30 AU from Sun)

Question 10

What is the Oort cloud?

Answer 10

A spherically symmetric cloud of cometary nuclei with orbital radii between 3000 - 10,000 AU (outside of the solar system)

source of all long period comets (which is how it was discovered)

Question 11

Why are there asteroids located on Jupiter’s orbit in specific places?

Answer 11

Due to Lagrange points (points of stability from the Sun)

Question 12

What is the solar system formed from?

Answer 12

A molecular cloud formed from remnants of a few stars

Cloud has mass of 2 - 3M_o and is 10,000 AU in size

Question 13

What happened to the cloud that formed the solar system?

Answer 13

It collapsed inwards under gravity (triggered by supernova due to isotropic signatures)

Conservation of angular momentum and the magnetic fields lead to a flattened disk

Question 14

What are the extreme orbits of planets due to?

Answer 14

Due to dynamical interactions (exchange angular momentum) with Oort cloud (motion tracked and showed hyperbolic orbit which did not originate in solar system)

Question 15

What is the cycle of formation of the solar system?

Answer 15

diffuse cloud -> dense cloud -> star with accretion disk -> stellar system -> mass loss (back to diffuse cloud)

(accretion disk material forms planets)

Question 16

What is the Minimum Mass Solar Nebula (MMSN)?

Answer 16

Minimum mass required to build all the bodies orbiting the Sun (roughly a few dozen times the mass of Jupiter)

Question 17

Where is the MMSN distributed and what does it contain?

What happens to the composition of the material in the disk over time?

Answer 17

In the original disk around the Sun
The disk contains dust and gas

The material changes as a function of distance from the star

Question 17

What is the snow line?

Answer 17

At a distance far away enough that the ice coatings on dust grains increase and material is formed which builds the core of planetesimals

The boundary between rock and rock + ice + gas on a density profile vs distance graph

Question 18

What is the snow line dependent of ?

Answer 18

Different radius depending on spectral type of host star (usually within a few AU)

Question 19

What process on the snow line helps grow larger grains/bodies?

Answer 19

Molecules collide with dust grains and coat the dust grains with ice mantle of water (e.g CO) so increase amount of solid material

The coating of ice increases the stickiness of dust grains and they grow larger bodies

Question 20

Where do rocky planets form?

Answer 20

Before the snow line

Question 21

To find the total disk mass using MMSN what do you need to consider?

Answer 21

the density profile of gas and da (2pi rdr)

Question 22

What does the MMSN equation indicate?

Answer 22

That planet formation is not 100% efficient so not entire MMSN mass will go to form planets

Question 23

At mm sizes, what are grains held together by?

Answer 23

Van de Waals forces and they feel gravitational pull in mid plane

Question 24

What do dust grains do when they reach mm sizes?

Answer 24

They decouple from gas

Question 25

What happens when grains condense?

Answer 25

The vertical component of the star’s gravity cause the dust to sediment out towards the midplane of disk

Question 26

What does the growth from cm-size particle to km-size planetesimals depend on?

Answer 26

The relative motions between the various bodies

Question 27

What is the gas in the disk, which is coupled to cm-sized materials, supported against?

Answer 27

Stellar gravity by a pressure in the radial directions and the gas orbits the star at slightly less than the Keplerian velocity (causing deceleration)

Question 28

For circular orbits, what must be balanced?

Answer 28

The effective gravity and the centrifugal acceleration

Question 29

What happens to large particles?

Answer 29

They encounter head wind which removes angular momentum and causes them to spiral inwards towards star

Question 30

What is a consequence of the difference in velocities of particles

Answer 30

Small cm-sized grains can be swept up by larger bodies while gas drag on metre sized planetesimals into radial motion

Question 31

Why does the time it takes for the transition from cm to km size planetesimal vary?

Answer 31

For the material to survive to form a planet, the transition from cm to km size needs to be quick unless the material is confined to sub disk and dragged at same Keplerian velocity

Question 32

What is the hypothesis linked to a nebula being inactive?

Answer 32

The dust and small particles settle into a layer thin enough to be gravitationally unstable to clumping and planetesimals (1km) are formed

Question 33

What is the hypothesis linked to a nebula being turbulent?

Answer 33

Growth of solid body continues via two-body collisions and they grow very quickly from mm to km size (physics not understood)

Molecular forces lead to km size via coagulation (va der walls binging energies broken down)

Once size > 1km, gravity takes over

Question 34

How was the solar system formed?

Answer 34

Dust settles gravitationally to midplane

(it’s composition changes with distance to sun due to different condensation temperatures for materials in disk e.g high T for silicates and oxides, low T for molecules)

Close to sun only high T materials

H and He are mostly in gas form

Question 35

When does grain growth occur?

Answer 35

When disk gets very thin

There is collisions and sticking making meteor-type bodies

Collisions and grav attraction lead to formation of planetesimals (km size)

Question 36

What is the time frame of grain growth?

Answer 36

From 100 planetesimals to 4 planetesimals in 150 Myr

Question 37

How long does it take for terrestrial planets to form?

Answer 37

takes less than 100Myr through giant impacts and depletes all available material

Question 38

How are Jovian planets formed?

Answer 38

In outer disk where lower temp so grains move slower and there is an increase of solids available leading to more rapid core growth (form faster than terrestrial)

Question 39

What happens when a core mass of Jovian planet is greater than 10 M_o?

Answer 39

Gravitational accretion of gaseous envelope (a runaway process) leading to a gas giant planet

accretion stops when there is no more material and gap in disk is formed

formed in less than 10Myr

Question 40

What does direct imaging use to detect planets?

Answer 40

Uses reflected light (this is very faint and difficult to observe) so successful for younger stars

Question 41

Why can direct imaging mainly capture young stars?

Answer 41

If star still has disk, it is young and planet is even younger and its luminosity comes from gravitational contractions (energy source) making it brighter than it would appear otherwise and brighter than reflection alone

Question 42

What is classified as a planet?

Answer 42

Stellar objects which are not sufficiently massive for fusion to ever consume majority of their deuterium

Question 43

What is brown dwarf?

Answer 43

Object which is large enough for deuterium fusion but not massive enough to sustain hydrogen fusion (similar luminosity to young planet)

Grav contraction is major source of energy

Question 44

What is the radial velocity technique for observing planets?

Answer 44

Doppler-shifting of spectral lines due to orbital motion about centre of mass (tug from planet) cause periodic variations in speed

Star moving towards us blueshifts and away it redshifts

(sensitive to short-period massive planets)

Question 45

What is the transit technique for detecting exoplanets?

Answer 45

Planet disrupts light from star when it passes in front of stars and causes reduction in light curve

most successful technique (sensitive to massive stars)

Question 46

What are some key observed properties of exoplanets?

Answer 46

Masses larger than Jupiter (most common is between Earth and Neptune size) < 10M_j

They move on highly eccentric orbits (0 to 1)

Planets closer than 10 R_o (less than 5AU)

Planets orbiting components of stellar binaries

Question 47

Why is each technique for observing exoplanets important?

Answer 47

Each technique finds planets at different distances (semi-major axis) from Earth and they are of different masses

(transit finds planets closest to us)

Question 48

What do observations of exoplanets surprisingly show?

Answer 48

exoplanet distribution is very different from solar system

Hot Jupiters: massive planets orbiting at 0.1AU from star

Super Earths: inner planets have masses greater than Earths but less than gas giants in our solar system

Planet mass function declines towards large masses

At large radii do not have circular orbits

Question 49

Where planets more likely to be found?

Answer 49

With stars that have high metallicity (Fe/H) as metals are proxy for how much dust is around a star

> 0.20

(Gas giants have high metallicity)

Question 50

What are the two ways in which exoplanets can form?

Answer 50

Gravitational instability in the disk: direct formation of gas-giant planets (self gravity of disk causes disk to form denser clumps)

Core accretion scenario (same as formation of solar system): growth from dust to rocky planets; big rocky planets accrete gas and form gas giants

Question 51

What is needed to estimate the conditions under which self-gravity wins over the stabilising effects of pressure forces and sheer?

Answer 51

The timescale for collapse to be shorter than the time scale on which sound waves can cross a clump, or shear forces can destroy it

Question 52

When will a clump collapse?

Answer 52

When Σ is large (disk is massive)

c_s is small (disk is cool, lower temp)

Ω is small (disk is large, big radius)

Question 53

What can’t grav instability explain?

Answer 53

Why planets aren’t made of different elements to their host stars

can’t account for presence of small bodies

hard to explain the enhanced abundance of heavy species in giant planets

Question 54

In which scenarios does gravitational instability arise in a real disk?

Answer 54

The formation of a massive disk

Clumpy infall onto a disk

Cooling of a disk from a stable to an unstable state

Slow accretion of mass

Close encounters with other stars/disk

Question 55

What is the process of core accretion in the formation of exoplanets?

Answer 55

Core formation -> hydrostatic growth -> runaway growth -> termination of accretion

Question 56

How can we account for hot Jupiters (need to be beyond snow line to form)?

Answer 56

Grav attraction between planet and non-uniform arrangement of gas generate torques that alter planet’s orbit and causes planet to migrate towards or away from star and alters orbital eccentricity

Direction and rate of migration vary depending on the mass of the planet and properties of gas disk

Question 57

What is Type I migration?

Answer 57

When the perturbation on planet is small enough that it does not alter gas disk

It affects Earth-mass planets which induce a linear perturbation in surrounding disk

migration rate is proportional to mass of planet and surface density of disk

Question 58

What is Type II migration?

Answer 58

Massive planets exert torque on disk and increases until star modifies disk structure

the strong torque repels gas from the vicinity of planet orbit, creating a GAP (due to angular momentum and removal of interior gas)

Affects Jupiter-mass objects

Question 59

How do planets migrate?

Answer 59

Through protoplanetary disk through tidal interactions (exchange of mass and angular momentum)