Astr 1050 Fri., Dec 5, 2003

Today: Extra Credit Articles

Finish Ch. 15, Cosmology

Start Solar System

Refining the Big Bang

Flatness Problem – why so close to a critical universe?

Horizon Problem – why is background all same T?

SOLVED BY AN “INFLATIONARY UNIVERSE”

“Grand Unified Theories” of combined Gravity/Weak/Electric/Nuclear forces predict very rapid expansion at very early time: “inflation”

When inflation ends, all matter moving away with v=v_escape (flat universe – curvature forced to zero)

Also solves horizon problem – everything was in causal contact

Implications of Slowing Expansion Rate

Our calculation of age T=1/H_o = 13.6 billion years assumed constant rate

Gravity should slow the expansion rate over time

If density is high enough, expansion should turn around

If expansion was faster in past, it took less time to get to present size

For “Flat” universe T = 2/3 * (1/H_o) = 9.3 billion years

contradiction with other ages if T is too small

Is the expansion rate slowing?

Look “into the past” to see if expansion rate was faster in early history.

To “look into the past” look very far away:

Find “H_o” for very distant objects, compare that to “H_o” for closer objects

Remember – we found H_o by plotting velocity (v_r) vs. distance

We found velocity v_r from the red shift (z)

We found distance by measuring apparent magnitude (m_v)
of known brightness objects

We can test for changing H_o by measuring m_v vs. z

Measuring deceleration using supernovae

Plot of m_v vs. z is really a plot of distance vs. velocity

If faint (Þdistant Þearlier) objects show slightly higher z
than expected from extrapolation based on nearby (present day) objects,
then expansion rate was faster in the past and has been decelerating

Surprise results from 1998 indeed do suggest accelerating expansion

May be due to “cosmological constant” proposed by Einstein

AKA “Dark energy” or “Quintessence”

“Cosmological constant”

General Relativity allows a repulsive term

Einstein proposed it to allow “steady state” universe

He decided it wasn’t needed after Hubble Law discovered

Is the acceleration right?

Could it be observational effect – dust dims distant supernova?

Could it be evolution effect – supernova were fainter in the past?

So far the results seem to stand up

Still being determined: 1) density, 2) cosmological constant

With cosmological constant included, can have a “flat universe” even with acceleration.

Given “repulsion” need to use relativistic “geometrical” definition of flatness, not the escape argument one given earlier.

Energy (and equivalent mass) from cosmological constant may provide density needed to produce flat universe.

Tests using
the Origin of Structure

Original “clumpiness” is a “blown up” version of the small fluctuations in density present early in the big bang and seen in the background radiation.

We can compare the structure implied to that expected from the “Grand Unification Theories”

Rate at which clumpiness grows depends on density of universe

Amount of clumpiness seems consistent with “flat universe” density

That means you need dark matter to make clumpiness grow fast enough

Acoustic Peaks in Background

Cosmology
as a testing ground for physics

Extremely high energies and densities in early Big Bang test “Grand Unification Theories” which combine rules for forces due to gravity, weak nuclear force, electric force, strong nuclear force

Extremely large masses, distances, times, test
General Theory of Relativity

Chapter 15: Cosmology

The Hubble Expansion – review+

Olber’s paradox

The Big Bang

Refining the Big Bang

Details of the Big Bang

General Relativity

Cosmological Constant

Origin of Structure

Chapter 16: Origin of the Solar System

Solar Nebula Hypothesis

Context for Understanding Solar System

Extrasolar Planets

Dust Disks, Doppler Shifts, Transits and Eclipses

Survey of the Solar System

Terrestrial Planets

Jovian Planets

Other “Stuff” including apparent patterns with application to the nebular hypothesis

Patterns in Motion

All planets orbit in almost the same plane (ecliptic, AKA Zodiac)

Almost all motion is counterclockwise as seen from the north:

All planets orbit in this direction

*Almost* all planets spin in same direction

with axes more-or-less perpendicular to ecliptic

Regular moons (like Galilean satellites and our own moon) orbit in this direction too

Planets are regularly spaced

steps increasing as we go outward

Spacing of Planets

Regular spacing of planets on a logarithmic scale

Each orbit is ~75% larger than the previous one

Need to include the asteroids as a “planet”

Solar Nebula Model

Planets form from disk of gas surrounding the young sun

Disk formation expected given angular momentum in collapsing cloud

Naturally explains the regular (counterclockwise) motion

Makes additional explicit predictions

Should expect planets as a regular part of the star formation process

Should see trends in composition with distance from sun

Should see “fossil” evidence of early steps of planet formation

Extra-Solar Planets

Hard to see faint planet right next to very bright star

Two indirect techniques available
(Like a binary star system but where 2nd “star” has extremely low mass)

Watch for Doppler “wobble” in position/spectrum of star

Watch for “transit” of planet which slightly dims light from star

About 100 planets discovered since 1996 See http://exoplanets.org/

Tend to be big (³Jupiter) and very close to star (easier to see)

Characteristics of “Planets”

Two types of planets

Terrestrial Planets: small, rocky material: inner solar system

Jovian Planets: large, H, He gas outer solar system

Small left-over material
provides “fossil” record of early conditions

Asteroids – mostly between orbits of Mars and Jupiter

Comets – mostly in outermost part of solar system

Meteorites – material which falls to earth

Slide 17

Patterns in Composition

Terrestrial Planets

Relatively small

Made primarily of rocky material:

Si, O, Fe, Mg perhaps with Fe cores
(Note – for earth H₂O is only a very small fraction of the total)

Jovian Planets

Relatively large

Atmospheres made of H₂, He, with traces of CH₄, NH₃, H₂O, ...

Surrounded by satellites covered with frozen H₂O

Within terrestrial planets inner ones tend to have higher densities
(when corrected for compression due to gravity)
       Planet Density Uncompressed Density
(gm/cm³)        (gm/cm³)

Mercury     5.44          5.30

Venus     5.24          3.96

Earth     5.50          4.07

Mars     3.94          3.73

(Moon)     3.36          3.40

Equilibrium Condensation Model

Start with material of solar composition material

(H, He, C, N, O, Ne, Mg, Si, S, Fe ...)

Material starts out hot enough that everything is a gas

May not be exactly true but is simplest starting point

As gas cools, different chemicals condense

First high temperature chemicals, then intermediate ones, then ices

Solids begin to stick together or accrete

snowflakes Þ snowballs (“Velcro Effect”)

Once large enough gravity pulls solids together into planetesimals

planetesimals grow with size

At some point wind from sun expels all the gas from the system

Only the solid planetesimals remain to build planets

Composition depends on temperature at that point (in time and space)

Gas can only remain if trapped in the gravity of a large enough planet

Growth of the Planetisimals

Once a planetisimal reaches critical size gravity takes over

Evidence of Assembly Process? Craters

Craters evident on almost all small “planets”

Clearing of the Nebula

Radiation pressure (pressure of light)

Will see present day effects in comets

Solar Wind

Strong solar winds from young T Tauri stars

Will see present day effects in comets

Sweeping up of debris into planets

Late Heavy Bombardment

Ejection of material by near misses with planets

Like “gravity assist maneuvers” with spacecraft

Origin of the comets

Patterns and Predictions

Why do different planets have different levels of geologic activity?

Why do different planets have different atmospheres?

What are ages of old “unaltered” planetary surfaces?

Should be similar, and agree roughly with age of Sun

Does composition of asteroids match predictions?

Lower temperature than Mars region: Hydrated silicates, etc.

What types of minerals do we see in meteorites?

What types of ices and minerals do we see in comets?

Chapter 17: Terrestrial Planets

Earth

History, Interior, Crust, Atmosphere

The Moon

In particular origin

Mercury

Venus

Mars

Including water (and life ?)

“Comparative Planetology”

Basis for comparisons is Earth

Properties of Earth

Similarities and differences with Mars and Venus help us understand Earth better (e.g., life, greenhouse effect, etc.)

Won’t spend much class time on basic properties (size, gravity, orbital period, length of day, etc.) but you should have some relative ideas about these (see “Data Files” in text). There will be a few exam questions!!!

Four Stages of Planetary Development

Earth’s Atmosphere: Greenhouse Effect

The Moon and Mercury

No atmosphere

Cratering is evidence of final planet assembly – lots to be learned from craters

Patterns in Geologic Activity

Judge age of surface by amount of craters:
more craters Þ more ancient surface
(for some objects, have radioactive age dates)

Moon “dead” after about 1 billion years

Mercury “dead” early in its lifetime

Mars active through ~1/2 of its lifetime

Venus active till “recent” times

Earth still active

Big objects cool off slower

Amount of heat (stored or generated) proportional to Volume ( so R³)

Rate of heat loss proportional (roughly) to Surface Area          (so R²)

Heat/(Unit Area) µ R³/R² = R     so activity roughly proportional to R

Same reason that big things taken out of oven cool slower than small things     (cake cools slower than cookies)

What is a crater?

Must think of them as caused by very large explosions from release of kinetic energy of impactor

Like a mortar shell – it isn’t the size of the shell which matters,
its how much energy you get out of the explosion

DO NOT think of them as just holes drilled into surface – think EXPLOSION

Kinetic Energy E = ½ m v²

v is roughly escape speed of earth

m = mass = volume * density (Consider a 1 km asteroid)

E

This is ~4500 ´ the size of the largest (~50 Mt) hydrogen bombs ever built
and this is for a relatively small size asteroid

Formation of an impact crater

Crater caused by the explosion

Impactor is melted, perhaps vaporized
by the kinetic energy released

Temporary “transient” crater is round

Gravity causes walls to slump inward forming “terraces”

Movement of material inward from all sides (trying to fill in the hole) may push up central peak in the middle.

Final crater is typically ~10 times
the size of the impactor

Examples of craters on the moon

Images on line at
The Lunar and Planetary Institute:
http://www.lpi.usra.edu/expmoon/lunar_missions.html

Detailed record of Apollo work at:
http://www.hq.nasa.gov/office/pao/History/alsj/frame.html

Effects of late impacts

Moon: Giant Impact Hypothesis

Explains lack of large iron core

Explains lack of “volatile” elements

Explains why moon looks a lot like earth’s mantle, minus the volatiles

Explains large angular momentum in the earth-moon system

Venus


	Today: Extra Credit Articles
	Finish Ch. 15, Cosmology
	Start Solar System


	Flatness Problem – why so close to a critical universe?
	Horizon Problem – why is background all same T?

	SOLVED BY AN “INFLATIONARY UNIVERSE”
		“Grand Unified Theories” of combined Gravity/Weak/Electric/Nuclear forces predict very rapid expansion at very early time: “inflation”
		When inflation ends, all matter moving away with v=v_escape (flat universe – curvature forced to zero)
		Also solves horizon problem – everything was in causal contact


	Our calculation of age T=1/H_o = 13.6 billion years assumed constant rate
	Gravity should slow the expansion rate over time
		If density is high enough, expansion should turn around











	If expansion was faster in past, it took less time to get to present size
	For “Flat” universe T = 2/3 * (1/H_o) = 9.3 billion years
		contradiction with other ages if T is too small


	Look “into the past” to see if expansion rate was faster in early history.

	To “look into the past” look very far away:
		Find “H_o” for very distant objects, compare that to “H_o” for closer objects

	Remember – we found H_o by plotting velocity (v_r) vs. distance
		We found velocity v_r from the red shift (z)
		We found distance by measuring apparent magnitude (m_v) of known brightness objects

		We can test for changing H_o by measuring m_v vs. z


	Plot of m_v vs. z is really a plot of distance vs. velocity
	If faint (Þdistant Þearlier) objects show slightly higher z than expected from extrapolation based on nearby (present day) objects, then expansion rate was faster in the past and has been decelerating









	Surprise results from 1998 indeed do suggest accelerating expansion
	May be due to “cosmological constant” proposed by Einstein
		AKA “Dark energy” or “Quintessence”


	General Relativity allows a repulsive term
		Einstein proposed it to allow “steady state” universe
		He decided it wasn’t needed after Hubble Law discovered

	Is the acceleration right?
		Could it be observational effect – dust dims distant supernova?
		Could it be evolution effect – supernova were fainter in the past?
		So far the results seem to stand up

	Still being determined: 1) density, 2) cosmological constant
		With cosmological constant included, can have a “flat universe” even with acceleration.
		Given “repulsion” need to use relativistic “geometrical” definition of flatness, not the escape argument one given earlier.
		Energy (and equivalent mass) from cosmological constant may provide density needed to produce flat universe.


	Original “clumpiness” is a “blown up” version of the small fluctuations in density present early in the big bang and seen in the background radiation.
		We can compare the structure implied to that expected from the “Grand Unification Theories”
	Rate at which clumpiness grows depends on density of universe
		Amount of clumpiness seems consistent with “flat universe” density
		That means you need dark matter to make clumpiness grow fast enough


	Extremely high energies and densities in early Big Bang test “Grand Unification Theories” which combine rules for forces due to gravity, weak nuclear force, electric force, strong nuclear force

	Extremely large masses, distances, times, test General Theory of Relativity


	The Hubble Expansion – review+
	Olber’s paradox
	The Big Bang
	Refining the Big Bang
	Details of the Big Bang
	General Relativity
	Cosmological Constant
	Origin of Structure


	Solar Nebula Hypothesis
		Context for Understanding Solar System
	Extrasolar Planets
		Dust Disks, Doppler Shifts, Transits and Eclipses
	Survey of the Solar System
		Terrestrial Planets
		Jovian Planets
		Other “Stuff” including apparent patterns with application to the nebular hypothesis


All planets orbit in almost the same plane (ecliptic, AKA Zodiac)
Almost all motion is counterclockwise as seen from the north:
	All planets orbit in this direction
	Almost all planets spin in same direction
		with axes more-or-less perpendicular to ecliptic
	Regular moons (like Galilean satellites and our own moon) orbit in this direction too
Planets are regularly spaced
	steps increasing as we go outward


	Regular spacing of planets on a logarithmic scale
	Each orbit is ~75% larger than the previous one
	Need to include the asteroids as a “planet”


	Planets form from disk of gas surrounding the young sun
		Disk formation expected given angular momentum in collapsing cloud
		Naturally explains the regular (counterclockwise) motion
	Makes additional explicit predictions
		Should expect planets as a regular part of the star formation process
		Should see trends in composition with distance from sun
		Should see “fossil” evidence of early steps of planet formation


	Hard to see faint planet right next to very bright star
	Two indirect techniques available (Like a binary star system but where 2nd “star” has extremely low mass)
		Watch for Doppler “wobble” in position/spectrum of star
		Watch for “transit” of planet which slightly dims light from star









	About 100 planets discovered since 1996 See http://exoplanets.org/
	Tend to be big (³Jupiter) and very close to star (easier to see)


	Two types of planets
		Terrestrial Planets: small, rocky material: inner solar system
		Jovian Planets: large, H, He gas outer solar system

	Small left-over material provides “fossil” record of early conditions
		Asteroids – mostly between orbits of Mars and Jupiter
		Comets – mostly in outermost part of solar system
		Meteorites – material which falls to earth


Terrestrial Planets
	Relatively small
	Made primarily of rocky material:
		Si, O, Fe, Mg perhaps with Fe cores (Note – for earth H₂O is only a very small fraction of the total)

Jovian Planets
	Relatively large
	Atmospheres made of H₂, He, with traces of CH₄, NH₃, H₂O, ...
	Surrounded by satellites covered with frozen H₂O

Within terrestrial planets inner ones tend to have higher densities (when corrected for compression due to gravity) Planet Density Uncompressed Density (gm/cm³) (gm/cm³)
	Mercury 5.44 5.30
	Venus 5.24 3.96
	Earth 5.50 4.07
	Mars 3.94 3.73
	(Moon) 3.36 3.40


	Start with material of solar composition material
		(H, He, C, N, O, Ne, Mg, Si, S, Fe ...)
	Material starts out hot enough that everything is a gas
		May not be exactly true but is simplest starting point

	As gas cools, different chemicals condense
		First high temperature chemicals, then intermediate ones, then ices
	Solids begin to stick together or accrete
		snowflakes Þ snowballs (“Velcro Effect”)
	Once large enough gravity pulls solids together into planetesimals
		planetesimals grow with size
	At some point wind from sun expels all the gas from the system
		Only the solid planetesimals remain to build planets
		Composition depends on temperature at that point (in time and space)
		Gas can only remain if trapped in the gravity of a large enough planet


	Once a planetisimal reaches critical size gravity takes over


	Radiation pressure (pressure of light)
		Will see present day effects in comets
	Solar Wind
		Strong solar winds from young T Tauri stars
		Will see present day effects in comets
	Sweeping up of debris into planets
		Late Heavy Bombardment
	Ejection of material by near misses with planets
		Like “gravity assist maneuvers” with spacecraft
		Origin of the comets


	Why do different planets have different levels of geologic activity?

	Why do different planets have different atmospheres?

	What are ages of old “unaltered” planetary surfaces?
		Should be similar, and agree roughly with age of Sun

	Does composition of asteroids match predictions?
		Lower temperature than Mars region: Hydrated silicates, etc.

	What types of minerals do we see in meteorites?

	What types of ices and minerals do we see in comets?


	Earth
		History, Interior, Crust, Atmosphere
	The Moon
		In particular origin
	Mercury
	Venus
	Mars
		Including water (and life ?)


	Basis for comparisons is Earth
	Properties of Earth
	Similarities and differences with Mars and Venus help us understand Earth better (e.g., life, greenhouse effect, etc.)
	Won’t spend much class time on basic properties (size, gravity, orbital period, length of day, etc.) but you should have some relative ideas about these (see “Data Files” in text). There will be a few exam questions!!!


	No atmosphere

	Cratering is evidence of final planet assembly – lots to be learned from craters


	Judge age of surface by amount of craters: more craters Þ more ancient surface (for some objects, have radioactive age dates)
		Moon “dead” after about 1 billion years
		Mercury “dead” early in its lifetime
		Mars active through ~1/2 of its lifetime
		Venus active till “recent” times
		Earth still active

	Big objects cool off slower
		Amount of heat (stored or generated) proportional to Volume ( so R³)
		Rate of heat loss proportional (roughly) to Surface Area (so R²)
		Heat/(Unit Area) µ R³/R² = R so activity roughly proportional to R

	Same reason that big things taken out of oven cool slower than small things (cake cools slower than cookies)


	Must think of them as caused by very large explosions from release of kinetic energy of impactor
		Like a mortar shell – it isn’t the size of the shell which matters, its how much energy you get out of the explosion
		DO NOT think of them as just holes drilled into surface – think EXPLOSION

		Kinetic Energy E = ½ m v²


		v is roughly escape speed of earth


		m = mass = volume * density (Consider a 1 km asteroid)




		E





		This is ~4500 ´ the size of the largest (~50 Mt) hydrogen bombs ever built and this is for a relatively small size asteroid


	Crater caused by the explosion
		Impactor is melted, perhaps vaporized by the kinetic energy released

	Temporary “transient” crater is round

	Gravity causes walls to slump inward forming “terraces”

	Movement of material inward from all sides (trying to fill in the hole) may push up central peak in the middle.


	Final crater is typically ~10 times the size of the impactor


	Images on line at The Lunar and Planetary Institute: http://www.lpi.usra.edu/expmoon/lunar_missions.html


	Detailed record of Apollo work at: http://www.hq.nasa.gov/office/pao/History/alsj/frame.html


	Explains lack of large iron core
	Explains lack of “volatile” elements

	Explains why moon looks a lot like earth’s mantle, minus the volatiles

	Explains large angular momentum in the earth-moon system