Post on 24-Jul-2020
https://www.sciencealert.com/periodicity-has-been-detected-in-a-repeating-fast-radio-burst
Today
in
Space
News:
Mysterious radio
signal from space
is repeating every
16 days
Astronomers have
found a deep
space radio burst
that pulses every
16 days
Study Points Describe an example of the Doppler Effect that involves sound.
Describe the pitch, frequencies, and wavelengths.
Describe an example of the Doppler Effect that involves light.
Describe the frequencies and wavelengths.
What is the Doppler Effect?
Describe how the Doppler Effect is used to measure the speed of a
star or planet relative to the Earth.
What is meant by a red shift or a blue shift?
Given the spectrum of a star and a reference spectrum, identify if
the star's spectrum is red or blue shifted, whether the Earth and the
star are moving toward or away from each other, and whether the
Earth and the star have large or small relative speeds.
What did Vera Rubin and her colleagues measure with the Doppler
Effect? What did they discover about a galaxy’s rotation? About a
galaxy’s mass?
What is gravitational lensing and why is it helpful?
Doppler Effect
and
Dark Matter
What can you learn from spectra?
• Temperature (energy)
• Density (from type of spectra)
• Composition (from lines)
• Moving toward or away (Doppler)
Demo: Sound
What is that sound?
Demo: Car horn blaring as it passes (example)*
Car moving at nearly constant speed
Listen to pitch and volume.
What changes in the car sound?
Does the volume change?
Note: Volume can change but this is NOT
the Doppler Effect.
What happened to the VOLUME of the horn?
1. sounded louder and louder as the source
approached and sounded fainter and fainter as
the source receded
2. stayed at a constant loudness as the source
approached then dropped to a fainter but
constant loudness as the source receded
3. stayed at the same constant loudness
throughout the motion
4. varied too much to tell what the volume was
doing
What happened to the VOLUME of the horn?
1. sounded louder and louder as the source
approached and sounded fainter and fainter as
the source receded*
2. stayed at a constant loudness as the source
approached then dropped to a fainter but
constant loudness as the source receded
3. stayed at the same constant loudness
throughout the motion
4. varied too much to tell what the volume was
doing
What changes in the car sound?
Does the volume change?
YES, but not due to the Doppler Effect.
The volume increases on approach and
decreases as it moves away.
Does the pitch (frequency) change?
What happened to the PITCH (frequency) of the horn?
1. became higher and higher as the source approached and became lower and lower as the source receded
2. stayed at a constant high pitch as the source approached and then dropped to a constant lower pitch as the source receded
3. stayed at the same constant pitch throughout the motion
4. stayed at the same pitch except at the moment the source passed
5. varied too much to tell what the pitch was doing
What happened to the PITCH (frequency) of the horn?
1. became higher and higher as the source approached and became lower and lower as the source receded
2. stayed at a constant high pitch as the source approached and then dropped to a constant lower pitch as the source receded*
3. stayed at the same constant pitch throughout the motion
4. stayed at the same pitch except at the moment the source passed
5. varied too much to tell what the pitch was doing
Volume
Time
Volume of car horn over time*
Frequency
Time
Frequency of car horn over time*
Doppler Effect
Shift in frequency (wavelength) due to
motion of source or observer or both.*
Used to measure:
• Motion toward or away
• Speed
Side Note:
Discovered by Christian Doppler in the mid-1800’s
Visual of waves from moving source:
http://www.acs.psu.edu/drussell/Demos/do
ppler/doppler.html
Drawing waves from moving source
Drawing waves…
If source is stationary
Source
( ( ( ( * ) ) ) ) )
←wave moves vsource = 0 wave moves→
If source is stationary
Source
( ( ( ( * ) ) ) ) )
←wave moves vsource = 0 wave moves→
If source moves
Source
( ( * ) ) ) ) )
Longer λ Shorter λ
Lower f Higher f
Red Shift Blue Shift
If source is stationary
Source
( ( ( ( * ) ) ) ) )
←wave moves vsource = 0 wave moves→
If source moves
Source
( ( * ) ) ) ) )
What if source moves faster?
( ( *)))))
Stretched more Compressed more
Higher speeds Bigger shifts*
Same results if source or observer
or both move
Approach Shift to shorter λ Blue shift*
(moving toward) higher f
Recede Shift to longer λ Red shift*
(moving away) lower f
Bigger shift (change) in λ Bigger speed*
Ex: “Earth’s Orbital Speed”
Predict: If Earth is at A, will the star’s
spectrum be red-shifted or blue-shifted?
Ex: “Earth’s Orbital Speed”
Predict: If Earth is at A, will the star’s
spectrum be red-shifted or blue-shifted?
Moving away
Red shifted*
Ex: “Earth’s Orbital Speed”
Ex: “Earth’s Orbital Speed”
Standard Emission Spectra for comparison
Absorption Spectra lines of starEarth is at “A”, so star is given designation “a”
Ex: “Earth’s Orbital Speed”
What color are these lines?
Ex: “Earth’s Orbital Speed”
What color are these lines?
Violet (bluish)
Ex: “Earth’s Orbital Speed”
Where is the red end of the spectrum?
Ex: “Earth’s Orbital Speed”
Blue end of spectrum
Red end of spectrum
Ex: “Earth’s Orbital Speed”
Is “a” red shifted or blue shifted?
Is the star (“a”) moving toward or away from Earth when compared to the standard spectra (top)?
Ex: “Earth’s Orbital Speed”
Blue shift
Red shift
Moving away from Earth = Red shift*
Ex: “Earth’s Orbital Speed”
Standard Emission Spectra
Is “b” red shifted or blue shifted?
Absorption Spectra lines of starEarth is at “B”, so star is given designation “b”
Standard Emission Spectra
Ex: “Earth’s Orbital Speed”
Blue shift*
Red shift*
= 546 nm = 643 nm
Spectrum of element Xo (at rest) | | |
Spectrum of star A (at rest) | | | ||
1. From the spectra above, you can conclude that star A
a. Contains the element Xo and only that element
b. Contains the element Xo and at least one more element
c. Does not contain the element Xo
d. There is not enough information to determine the composition
= 546 nm = 643 nm
Spectrum of element Xo (at rest) | | |
Spectrum of star A (at rest) | | | ||
1. From the spectra above, you can conclude that star A
a. Contains the element Xo and only that element
b. Contains the element Xo and at least one more element
c. Does not contain the element Xo
d. There is not enough information to determine the composition
= 546 nm = 643 nm
Spectrum of element Xo (at rest) | | |
Spectrum of star A | | | ||
2. From the spectra above, you can conclude that star A
a. Contains the element Xo and only that element
b. Contains the element Xo and at least one more element
c. Does not contain the element Xo
d. There is not enough information to determine the composition
= 546 nm = 643 nm
Spectrum of element Xo (at rest) | | |
Spectrum of star A | | | ||
2. From the spectra above, you can conclude that star A
a. Contains the element Xo and only that element
b. Contains the element Xo and at least one more element
c. Does not contain the element Xo
d. There is not enough information to determine the composition
3. From the spectra above, you can conclude that Earth and star A
a. Are moving toward each other
b. Are moving away from each other
c. There is not enough information to determine the relative direction of motion of Earth and the star.
= 546 nm = 643 nm
Spectrum of element Xo (at rest) | | |
Spectrum of star A | | | ||
Blue shifted or red shifted?
3. From the spectra above, you can conclude that Earth and star A
a. Are moving toward each other
b. Are moving away from each other
c. There is not enough information to determine the relative direction of motion of Earth and the star.
Blue Shifted or Red Shifted?
Moving Away = Red Shifted
= 546 nm = 643 nm
Spectrum of element Xo (at rest) | | |
Spectrum of star A | | | ||
4. From the spectra above, you can conclude that
a. Star A is moving faster away from element Xo than star B
b. Star B is moving faster away from element Xo than star A
c. There is not enough information to determine the relative speed of each star to element Xo.
Both star A and B are moving away from Xo and are red shifted.
Astronomers can calculate the speed from the wavelength difference.
= 546 nm = 643 nm
Spectrum of element Xo (at rest) | | |
Spectrum of star A | | | ||
Spectrum of star B | | | ||
4. From the spectra above, you can conclude that
a. Star A is moving faster away from element Xo than star B
b. Star B is moving faster away from element Xo than star A
c. There is not enough information to determine the relative speed of each star to element Xo.
Both star A and B are moving away from Xo and are red shifted.
Astronomers can calculate the speed from the wavelength difference.
= 546 nm = 643 nm
Spectrum of element Xo (at rest) | | |
Spectrum of star A | | | ||
Spectrum of star B | | | ||
Apply the Doppler Effect to Galaxies
What can we learn?
http://nssdc.gsfc.nasa.gov/image/astro/hst_ngc4414_9925.jpg
Fritz Zwicky – 1930s
• Galaxies in clusters are moving
too fast
• Something holding them together
• Proposed dark matter to explain galaxy motion
http://ned.ipac.caltech.edu/level5/Biviano2/Biviano4_2.html
Vera Rubin – 1960s
• Studied rotational speeds of galaxies*
• Galaxies have bright centers
• Expect most mass at center
• Expect inner stars to move faster and outer stars to move slower
• Based on Kepler’s laws of motion, like solar system
http://astro.berkeley.edu/~gmarcy/women/rubin.htmlhttp://nssdc.gsfc.nasa.gov/image/astro/hst_ngc4414_9925.jpg
• Kepler’s laws didn’t work and do not apply to galaxies
• Instead, she applied the Doppler Effect to detect speeds at different places in the galaxies
Vera Rubin – 1960s
• Outer stars orbit about same speed as inner ones (galaxy rotation problem)*
• Lots of mass far from center*
• 90% of mass is unseen = Dark Matter*
Gravitational Lensing – proposed by
Einstein and Zwicky
From NASA: https://www.universetoday.com/wp-content/uploads/2014/11/Gravitational-lensing-galaxyApril12_2010.jpg
Gravitational Lensing – 1980s
• Gravity bends light*
• Creates multiple images or distorts into arcs
• Confirms dark matter
• Able to see objects behind shining mass*
Hubble Sees a Smiling Lens
https://www.nasa.gov/content/hubble-sees-a-smiling-lens Feb.10, 2015
Lots of Gravitational LensingEarly galaxies, 600 million years after Big Bang
https://www.nasa.gov/feature/goddard/hubble-spies-big-bang-frontiersOct. 22, 2015
Bullet Cluster
• 2 clusters of galaxies moving apart after colliding
• Red: X-rays (colliding gas)
• Blue: dark matter (gravitational lensing)
http://antwrp.gsfc.nasa.gov/apod/ap080823.html
Dark Matter
Matter “seen” by its gravitational pull (lensing)
• Motions of galaxies within clusters (Zwicky)
• Rotation of galaxies (Rubin)
• Bending of distant galaxy light by
intervening clusters (Gravitational Lensing)
• Collision of two clusters of galaxies
• Planck spacecraft: about 5% common
matter, 25% dark matter, 70% dark energy
Dark Matter
What is it?
We are much more certain what dark matter is
NOT than we are what it is. – NASA
– not visible matter, not baryons, not antimatter,
not black holes
Possibly
• MACHOs or WIMPs
– WIMPs are now seen as much more likely
– LHC, Fermi telescope, underground neutrino
experiments… all still looking.
https://science.nasa.gov/astrophysics/focus-areas/what-is-dark-energy
Cosmos: A Spactime Odyssey (2014)
with Neil deGrasse Tyson
Episode 13: Unafraid of the Dark
Journey into the unknown forces of the universe.
Observation Projects
Planetarium (10 pts)
Start: Jan 28
Due: May 12
• Moon Phases (10 pts)
• Start Jan. 23
• Due March 5
• Star Gazing (20 pts)
• Start Jan 21
• Due May 12
• Mandatory
Moon Craters (10 pts)
Start: Jan 30
Due: May 12
• Telescope (20 pts)
• Start Jan. 30
• Due May 12
• Mandatory
Astronomy News
Evaluation (20 pts)
Start: Feb 20
Due: March 19
Mandatory
Homework
Continue STUDY POINTS
Lab – no lab today!
D2L Quizzes (#5 due today, #6 starts today)
Turn in student conference attendance