Astr 1050 Wed., Apr 7, 2004

Today: Finish Chapter 14, Active Galaxies

Start Ch. 15, Cosmology

Quasar Images III: “Starburst-Quasar”

What makes an AGN active?

Need a supply of gas to feed to the black hole

(Black holes from 1 million to >1 billion solar masses!

Scales as a few percent of galaxy bulge mass.)

Collisions disturb regular orbits of stars and gas clouds

Could feed more gas to the central region

Galactic orbits were less organized as galaxies were forming, also recall the “hierarchical” galaxy formation

Expect more gas to flow to central region when galaxies are young => Quasars (“quasar epoch” around z=2 to z=3)

Most galaxies may have massive black holes in them

They are just less active now because gas supply is less

Gravitational Lensing

For more information, movies:

A nice website: http://www.mssl.ucl.ac.uk/www_astro/agn/agn_beginners.html

Other links on the website will take you to movies showing quasar structure, and discussing unified models.

Chapter 14: Galaxies with Active Nuclei

Discovery of Active Galactic Nuclei (AGN)

Seyfert Galaxies and Radio Sources

The Unified Model

Black Holes in Galaxies, disks, orientation, +

Quasars

Distances and Relativistic Redshifts

Quasars as extreme AGN

Evolution of Quasars/Galaxies

Gravitational Lensing

Chapter 15: Cosmology

Olber’s paradox

The Hubble Expansion – review+

The Big Bang

Refining the Big Bang

Details of the Big Bang

General Relativity

Cosmological Constant

Origin of Structure

Olber’s Paradox:
Why is the night sky dark?

If we are in a forest which extends far enough then

In any direction we will just be looking at the trunk of some
tree.

Olber’s Paradox:
Why is the night sky dark?

If we are in a universe which extends far enough then

In any direction we will just be looking at the surface of some star.

Olber’s Paradox: Answer

It could be that the Universe doesn’t extend far enough –
but that doesn’t seem to be the right answer

The finite age of the universe limits how far we can see:
If it has age T, we can only see out as far as d=c´T
The light from farther stars hasn’t had time to reach us yet

Basic Cosmology Assumptions

Homogeneity – matter is uniformly spread across the universe on large scales

Isotropy – the universe looks the same in all directions, again strictly true on large scales

Universality – laws of physics apply everywhere in the universe (being challenged!)

These lead to the “cosmological principle” which says that any observer in any galaxy in the universe should see essentially the same features of the universe.

The Hubble Law and the Age of the Universe
H_o = 72 ±8 km/s/Mpc

Hubble Law: Everyone sees same expansion

Universal Expansion: Balloon Analogy

Simulation of a “closed” spherical universe expanding:

http://www.astro.ucla.edu/~wright/Balloon2.html

The points here are that

Expansion looks the same from each galaxy

There is no “center” of the universe

Galaxies do not expand

Photons are redshifted because space itself is expanding

Early History of Universe?
Run time “backwards” to understand

Density goes up as expansion “reverses”

Temperature goes up as material is compressed

The early universe was very hot and dense.

This is the essence of the “Big Bang” model, which has numerous testable predictions.

Consider a molecular H₂ , He gas as it gets hotter

H₂ molecules break apart into H atoms

H atoms loose their electrons

He atoms lose their electrons

He nuclei break apart into protons, neutrons

Protons and neutrons break apart into quarks

More exotic massive unstable particles are created

You get more and shorter wavelength photons

You get a quasi-equilibrium between photons and matter

High energy photons Û (particles + antiparticles)

Critical points with time running forward

10^-45 sec Quantum gravity? Physics not understood

10^-34 sec 10²⁶ K Nuclear strong force/electro weak force separate
(inflation, matter/antimatter asymmetry)

10^-7 sec 10¹⁴K Protons, AntiprotonsÛphotons

10^-4 sec 10¹² K Number of protons frozen

    4   sec            10¹⁰ K                  Number of electrons frozen

    2   min Deuterium nuclei begins to survive

    3   min 10⁹ K Helium nuclei begin to survive

30   min           10⁸ K                     T, r too low for more nuclear reactions
(frozen number of D, He -- critical prediction)

300,000 yr 10⁴ K Neutral H atoms begin to survive
(frozen number of photons – critical prediction)

1 billion yr Galaxies begin to form

13 billion yr Present time

First prediction from Big Bang model:
Cosmic Background Radiation

Look out (and back in time) to place where H became neutral

Beyond that the high density ionized H forms an opaque “wall”

Originally 3000 K blackbody radiation

The material that emitted it was moving away from us at extreme speed

That v produces extreme redshift (z=1000), so photons all appear much redder, so T appears cooler

With red shift, get 2.7 K Planck blackbody

Should be same in all directions

Cosmic Microwave Background Observations

First detected by Wilson and Penzias in 1960’s

Serendipitous detection – thought is was noise in their radio telescope but couldn’t find cause. Only later heard of theoretical predictions

Best spectrum observed by COBE satellite

Red curve is theoretical prediction

43 Observed data points plotted there
error bars so small they are covered by curve.

it is covered by curve.

Isotropy also measured by COBE

T varies by less than 0.01 K across sky

Small “dipole” anisotropy seen

Blue = 2.721 Red = 2.729

Caused by motion of Milky Way falling towards the Virgo supercluster.

Second prediction from Big Bang Model:
Abundance of the light elements

Big Bang Nucleosynthesis

T, r both high enough at start to fuse protons into heavier elements

T, r both dropping quickly so only have time enough to fuse a certain amount.

Simple models of expansion predict 25% abundance He

25% is the amount of He observed

Abundance of ²H, ³He, ⁷Li depends on r_{normal matter}

Suggests r_{normal matter} is only 5% of r_critical

But we need to also consider “dark matter” and its gravity

Main Tests of the Big Bang

Hubble Expansion (not a test really, inspiration)

Cosmic Microwave Background

Abundance of light elements

Refinements of Big Bang Still Being Tested

Possible “cosmological constant”

Very early history:

particle/antiparticle asymmetry

“inflation” -- Details of very early very rapid expansion

small r, T fluctuations which lead to galaxies

Will the expansion stop?

Is there enough gravity (enough mass) to stop expansion?

Consider an simple model as first step (full model gives same answer)

Treat universe as having center

Assume only Newtonian Gravity applies

Does a given shell of matter have escape velocity? Is v > v_esc ?

General Relativistic Description

What we call “gravity” is really bending of our 3-d space in some higher dimension.

Bending, or “curvature of space” is caused by presence of mass.

More mass implies more bending.

If bending is enough, space closes back on itself,
just like 2-d surface of earth is bent enough in 3rd dimension
to close back on itself.

Mass and the Curvature of Space

First consider case with little mass (little curvature)

Ant (in 2-d world) can move in straight line from point A to point B.

Add mass to create curvature in extra dimension invisible to the ant.

   In trying to go from point A to
   point B, fastest path is curved one
   which avoids the deepest part of the

   well.

Ant will be delayed by the extra

motion in the hidden third

dimension.

Both effects verified in sending photons past the sun:

Bending of starlight during solar eclipse

Delay in signals from spacecraft on
opposite side of the sun

How to test the amount of curvature

Measure the circumference of a circle as you get farther and farther from the origin:

Does it go up as expected from (2 p R)?

It goes up slower in a positively curved world.

How high is the density?

Not nearly enough normal matter to provide critical density

We keep seeing effects of gravity from “dark matter”

Higher rotation speeds in our own galaxy

Higher relative velocities of galaxies in clusters

Rate at which matter clumps together to form galaxy clusters

Gravitational lensing from galaxies, clusters

May be 10 to 100 times as much “dark matter” as visible matter

What might make up the “dark matter”? Possibilities include

MACHOs (massive compact halo objects) http://www.astro.ucla.edu/~wright/microlensing.html

but ²H, Li, Be abundance suggest no more than 5% can be “baryonic”

WIMPs (weakly interacting massive particles) predicted by some GUT’s

Mass of neutrinos

Mass equivalent of “cosmological constant” energy

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


	Today: Finish Chapter 14, Active Galaxies
	Start Ch. 15, Cosmology


		Need a supply of gas to feed to the black hole
		(Black holes from 1 million to >1 billion solar masses!
		Scales as a few percent of galaxy bulge mass.)

	Collisions disturb regular orbits of stars and gas clouds
		Could feed more gas to the central region

	Galactic orbits were less organized as galaxies were forming, also recall the “hierarchical” galaxy formation
		Expect more gas to flow to central region when galaxies are young => Quasars (“quasar epoch” around z=2 to z=3)

	Most galaxies may have massive black holes in them
	They are just less active now because gas supply is less


	A nice website: http://www.mssl.ucl.ac.uk/www_astro/agn/agn_beginners.html
	Other links on the website will take you to movies showing quasar structure, and discussing unified models.


	Discovery of Active Galactic Nuclei (AGN)
		Seyfert Galaxies and Radio Sources
	The Unified Model
		Black Holes in Galaxies, disks, orientation, +
	Quasars
		Distances and Relativistic Redshifts
		Quasars as extreme AGN
		Evolution of Quasars/Galaxies
		Gravitational Lensing


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


	If we are in a forest which extends far enough then
	In any direction we will just be looking at the trunk of some tree.


	If we are in a universe which extends far enough then
	In any direction we will just be looking at the surface of some star.



	It could be that the Universe doesn’t extend far enough – but that doesn’t seem to be the right answer

	The finite age of the universe limits how far we can see: If it has age T, we can only see out as far as d=c´T The light from farther stars hasn’t had time to reach us yet


	Homogeneity – matter is uniformly spread across the universe on large scales

	Isotropy – the universe looks the same in all directions, again strictly true on large scales

	Universality – laws of physics apply everywhere in the universe (being challenged!)

		These lead to the “cosmological principle” which says that any observer in any galaxy in the universe should see essentially the same features of the universe.


	Simulation of a “closed” spherical universe expanding:
	http://www.astro.ucla.edu/~wright/Balloon2.html

	The points here are that
		Expansion looks the same from each galaxy
		There is no “center” of the universe
		Galaxies do not expand
		Photons are redshifted because space itself is expanding


	Density goes up as expansion “reverses”

	Temperature goes up as material is compressed
	The early universe was very hot and dense.
	This is the essence of the “Big Bang” model, which has numerous testable predictions.


	H₂ molecules break apart into H atoms
	H atoms loose their electrons
	He atoms lose their electrons
	He nuclei break apart into protons, neutrons
	Protons and neutrons break apart into quarks
	More exotic massive unstable particles are created

	You get more and shorter wavelength photons
	You get a quasi-equilibrium between photons and matter
		High energy photons Û (particles + antiparticles)


	10^-45 sec Quantum gravity? Physics not understood
	10^-34 sec 10²⁶ K Nuclear strong force/electro weak force separate (inflation, matter/antimatter asymmetry)
	10^-7 sec 10¹⁴K Protons, AntiprotonsÛphotons
	10^-4 sec 10¹² K Number of protons frozen
	4 sec 10¹⁰ K Number of electrons frozen
	2 min Deuterium nuclei begins to survive
	3 min 10⁹ K Helium nuclei begin to survive
	30 min 10⁸ K T, r too low for more nuclear reactions (frozen number of D, He -- critical prediction)
	300,000 yr 10⁴ K Neutral H atoms begin to survive (frozen number of photons – critical prediction)
	1 billion yr Galaxies begin to form
	13 billion yr Present time


	Look out (and back in time) to place where H became neutral
	Beyond that the high density ionized H forms an opaque “wall”
	Originally 3000 K blackbody radiation
	The material that emitted it was moving away from us at extreme speed
	That v produces extreme redshift (z=1000), so photons all appear much redder, so T appears cooler
	With red shift, get 2.7 K Planck blackbody
	Should be same in all directions


First detected by Wilson and Penzias in 1960’s
	Serendipitous detection – thought is was noise in their radio telescope but couldn’t find cause. Only later heard of theoretical predictions

Best spectrum observed by COBE satellite
	Red curve is theoretical prediction
	43 Observed data points plotted there error bars so small they are covered by curve.
	it is covered by curve.

Isotropy also measured by COBE
	T varies by less than 0.01 K across sky
	Small “dipole” anisotropy seen
		Blue = 2.721 Red = 2.729
		Caused by motion of Milky Way falling towards the Virgo supercluster.


Big Bang Nucleosynthesis
	T, r both high enough at start to fuse protons into heavier elements
	T, r both dropping quickly so only have time enough to fuse a certain amount.

	Simple models of expansion predict 25% abundance He
		25% is the amount of He observed
	Abundance of ²H, ³He, ⁷Li depends on r_{normal matter}
		Suggests r_{normal matter} is only 5% of r_critical
		But we need to also consider “dark matter” and its gravity


Hubble Expansion (not a test really, inspiration)
Cosmic Microwave Background
Abundance of light elements Refinements of Big Bang Still Being Tested
	Possible “cosmological constant”
	Very early history:
		particle/antiparticle asymmetry
		“inflation” -- Details of very early very rapid expansion
		small r, T fluctuations which lead to galaxies


	Is there enough gravity (enough mass) to stop expansion?
	Consider an simple model as first step (full model gives same answer)
		Treat universe as having center
		Assume only Newtonian Gravity applies
		Does a given shell of matter have escape velocity? Is v > v_esc ?


	What we call “gravity” is really bending of our 3-d space in some higher dimension.
	Bending, or “curvature of space” is caused by presence of mass.
	More mass implies more bending.

	If bending is enough, space closes back on itself, just like 2-d surface of earth is bent enough in 3rd dimension to close back on itself.


	First consider case with little mass (little curvature)

	Ant (in 2-d world) can move in straight line from point A to point B.

	Add mass to create curvature in extra dimension invisible to the ant.

	In trying to go from point A to point B, fastest path is curved one which avoids the deepest part of the
	well.

	Ant will be delayed by the extra
	motion in the hidden third
	dimension.

	Both effects verified in sending photons past the sun:
	Bending of starlight during solar eclipse
	Delay in signals from spacecraft on opposite side of the sun


	Measure the circumference of a circle as you get farther and farther from the origin:

	Does it go up as expected from (2 p R)?

	It goes up slower in a positively curved world.


Not nearly enough normal matter to provide critical density
We keep seeing effects of gravity from “dark matter”
	Higher rotation speeds in our own galaxy
	Higher relative velocities of galaxies in clusters
	Rate at which matter clumps together to form galaxy clusters
	Gravitational lensing from galaxies, clusters
	May be 10 to 100 times as much “dark matter” as visible matter


What might make up the “dark matter”? Possibilities include
	MACHOs (massive compact halo objects) http://www.astro.ucla.edu/~wright/microlensing.html
		but ²H, Li, Be abundance suggest no more than 5% can be “baryonic”
	WIMPs (weakly interacting massive particles) predicted by some GUT’s
	Mass of neutrinos
	Mass equivalent of “cosmological constant” energy


	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