Download runaway - Astronomy & Astrophysics Group

Document related concepts

Dark matter wikipedia , lookup

Anthropic principle wikipedia , lookup

Gamma-ray burst wikipedia , lookup

International Ultraviolet Explorer wikipedia , lookup

Outer space wikipedia , lookup

Modified Newtonian dynamics wikipedia , lookup

Astronomical unit wikipedia , lookup

Hubble Space Telescope wikipedia , lookup

Observational astronomy wikipedia , lookup

Wilkinson Microwave Anisotropy Probe wikipedia , lookup

Galaxy wikipedia , lookup

Dark energy wikipedia , lookup

Universe wikipedia , lookup

Malmquist bias wikipedia , lookup

Timeline of astronomy wikipedia , lookup

Galaxy Zoo wikipedia , lookup

Cosmic microwave background wikipedia , lookup

Fine-tuned Universe wikipedia , lookup

Big Bang wikipedia , lookup

Shape of the universe wikipedia , lookup

Ultimate fate of the universe wikipedia , lookup

Non-standard cosmology wikipedia , lookup

Flatness problem wikipedia , lookup

Cosmic distance ladder wikipedia , lookup

Physical cosmology wikipedia , lookup

Hubble Deep Field wikipedia , lookup

Transcript
The Runaway
Universe
Dr Martin Hendry
Dept of Physics and Astronomy
University of Glasgow
Cosmology – the study of
the Universe as a whole:
• Origin
• Evolution
• Eventual Fate
Cosmological theories depend
on the available data
Ptolemy
90 – 168 AD
Almagest (c 140 AD)
Earth-Centred
Universe
Nicolaus
Copernicus
1473 – 1543 AD
“In the true centre of everything
resides the Sun”
De Revolutionibus Orbis (1543)
Galileo Galilei:
1564 – 1642 AD
Galileo Galilei:
1564 – 1642 AD
“I have observed the nature and the material of the
Milky Way. With the aid of the telescope this has been
scrutinized so directly and with such ocular certainty
that all the disputes which have vexed philosophers
through so many ages have been resolved, and we are at
last freed from wordy debates about it.
The galaxy is, in fact, nothing but a collection of
innumerable stars grouped together in clusters. Upon
whatever part of it the telescope is directed, a vast
crowd of stars is immediately presented to view. Many
of them are rather large and quite bright, while the
number of smaller ones is quite beyond calculation.”
from The Starry Messenger (1610)
Herschel’s Milky Way (1790)
The stars are VERY far away. The
nearest star (after the Sun) is about
40 million million km from the Earth.
It takes light more than 4 years to
cross this distance (travelling at a
speed of 300,000 km per second)
If the Earth-Sun distance were the
width of this screen, the nearest star
would be in Rome !!!
Measuring Astronomical Distances: Parallax
Measuring Astronomical Distances: Parallax
Even the nearest star shows a
parallax shift of only 1/2000th
the width of the full Moon
Measuring Astronomical Distances:
Inverse Square Law
Brightness falls off with the square of the distance, because
surface area of a sphere increases with the square of the radius
Measuring Astronomical Distances:
Inverse Square Law
Cepheid Variables: Cosmic Yardsticks
Henrietta Leavitt
1908-1912
Herschel’s Milky Way (1790)
Shapley’s
Model (1915)
Early 20th Century
The nature of
the nebulae?…
Gas clouds within the Milky Way,
or Island Universes?….
The Great Debate, 1920
Shapley vs Curtis
at the National Academy of Sciences
The Great Debate, 1920
Shapley vs Curtis
at the National Academy of Sciences
Shapley argues successfully
that the nebulae are within
the Milky Way
1922: Hubble finds
Cepheids in the Great
Nebula in Andromeda
Hubble measured distances to
dozens of nearby nebulae
Even the nearest,
in Andromeda, was
millions of light
years distant
Hubble also measured
the shift in colour, or
wavelength, of the light
from distant galaxies.
Galaxy
Hubble also measured
the shift in colour, or
wavelength, of the light
from distant galaxies.
Galaxy
Laboratory
Hubble also measured
the shift in colour, or
wavelength, of the light
from distant galaxies.
Galaxy
Laboratory
Hubble’s Law: 1922
Distant galaxies are receding from us with a
velocity proportional to their distance
Hubble’s Interpretation
‘Recession of the Nebulae’
caused not by the motion
of galaxies through space,
but the expansion of space
itself between the galaxies
Einstein’s General Relativity
Einstein’s Relativity
“Matter tells spacetime how
to curve,
and spacetime
Matter
causestells
space
matter how to move”
to curve or warp
How fast is the Universe expanding?
H0?
Hubble’s Law
V = H0 d
H0 has units of (time)-1 – usually measured
in kilometres per second per Megaparsec
Hubble’s Law
V = H0 d
H0 has units of (time)-1 – usually measured
in kilometres per second per Megaparsec
1 pc = 3.26 light years = 3
x 1016
m
Hubble’s Law
V = H0 d
H0 has units of (time)-1 – usually measured
in kilometres per second per Megaparsec
1 pc = 3.26 light years = 3
x 1016
m
H0-1 = Hubble time = timescale for the
expansion age of the Universe
Hubble’s Law
V = H0 d
Hubble’s original work gave H0 = 500
(in conflict with Geological timescale)
‘Modern’ values: dichotomy between
H0 = 50, and H0 = 100
(with small statistical error)
????
Principal difficulty has been local
distortions in ‘Hubble flow’
e.g. spectrum of
M31 is blueshifted
Galaxies are clustered
Structure in the Universe
assembled by gravity
Galaxies are clustered
Structure in the Universe
assembled by gravity
Locally, gravity
sufficient to overcome
cosmic expansion
Galaxies are clustered
Structure in the Universe
assembled by gravity
Locally, gravity
sufficient to overcome
cosmic expansion
On larger scales,
expansion diluted:
galaxies have peculiar
velocity on top of
Hubble velocity
Main local distortion due to Virgo cluster
Problem:
Need to determine H0
from remote galaxies,
where peculiar motions
are less important….
….but….
We cannot use primary
distance indicators to
measure their distance
Need Distance Ladder!!
HST Key Project, led by Wendy Freedman
Measure Cepheid distances to ~30 nearby galaxies,
Link Cepheids to Secondary distance indicators
HST has ‘bypassed’
one stage of the
Distance Ladder, by
observing Cepheids
beyond the Local
Group of galaxies
HST has ‘bypassed’
one stage of the
Distance Ladder, by
observing Cepheids
beyond the Local
Group of galaxies
This has dramatically
improved
measurements of H0
Virgo Cluster galaxy
M100, 60 million light years distant…..
HST data
also allows
correction
for the
dimming
effects of
DUST
Must ensure that
remote galaxy data
are free from
Selection Effects
e.g. intrinsically
brighter or bigger?…
Must ensure that
remote galaxy data
are free from
Selection Effects
e.g. intrinsically
brighter or bigger?…
Malmquist Bias
Must ensure that
remote galaxy data
are free from
Selection Effects
e.g. intrinsically
brighter or bigger?…
Malmquist Bias
Must ensure that
remote galaxy data
are free from
Selection Effects
e.g. intrinsically
brighter or bigger?…
Malmquist Bias
H0 = 70  7
Age of the Universe = 10 – 16 billion years
(depends if the expansion is speeding up or slowing down)
Will the Universe continue
to expand forever?
To find out we need to compare the expansion
rate now with the expansion rate in the distant
past…
Is the Universe speeding
up or slowing down?
Answer depends on the geometry of the
Universe
Einstein’s General Relativity
Einstein’s Relativity
“Matter tells spacetime how
to curve,
and spacetime
Matter
causestells
space
matter how to move”
to curve or warp
Answer depends on the geometry of the
Universe
Closed
Answer depends on the geometry of the
Universe
Closed
Open
Answer depends on the geometry of the
Universe
Closed
Open
Flat
We can measure the geometry, and compare the
expansion rate, using Supernovae….
Type Ia Supernova
White dwarf star with a massive binary companion. Accretion
pushes white dwarf over the Chandrasekhar limit, causing
thermonuclear disruption
Good standard candle because:Narrow range of luminosities at maximum light
Observable to very large distances
We can measure the geometry, and compare the
expansion rate, using Supernovae….
Geometry of the Universe affects
the relationship between distance
and redshift of the supernovae
Closed
Open
Flat
We can measure the geometry, and compare the
expansion rate, using Supernovae….
….and the Cosmic Background Radiation
Early Universe too hot for neutral atoms
Free electrons scattered light (as in a fog)
After 300,000 years, cool enough for atoms; fog clears!
Background radiation predicted
in 1950s and 1960s by Gamov,
Dicke, Peebles.
Discovered in 1965 by Penzias
and Wilson
Robert Dicke
Arno Penzias and Robert Wilson
Jim Peebles
Cosmic Background Explorer (CoBE), launched 1989
CoBE map of temperature across the sky
CoBE map of temperature across the sky
CMBR ‘ripples’ are the
seeds of today’s galaxies
Galaxy formation is highly
sensitive to the pattern, or
power spectrum, of CMBR
temperature ripples
Position of first peak
sensitive probe of the
geometry of the Universe
Microwave Anisotropy Probe
First WMAP results published February 2003
From Bennett et al (2003)
First year WMAP results published Tuesday 11th Feb
Position of first peak
sensitive probe of the
geometry of the Universe
Answer depends on the geometry of the
Universe
Closed
Open
Flat
Results:
The geometry of the Universe is FLAT
The Universe will continue to expand
indefinitely
The expansion is accelerating
What is driving the cosmic acceleration?…
Cosmological Constant?
Quintessence?
Dust?….
The future of the Universe:-
No
Big Crunch!!!