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Name: Katie Avalo
ExtraSolar Planets – Student Guide Background Material Complete the following sections after reviewing the background pages entitled Introduction,
Doppler Shift, Center of Mass, and ExtraSolar Planet Detection. Question 1:
Label the positions on the star’s orbit with the letters corresponding to the labeled
positions of the radial velocity curve. Remember, the radial velocity is positive when the star is
moving away from the earth and negative when the star is moving towards the earth. Question 2:
Label the positions on the planet’s orbit with the letters corresponding to the labeled
positions of the radial velocity curve. Hint: the radial velocity in the plot is still that of the star, so
for each of the planet positions determine where the star would be and in which direction it
would be moving.
NAAP – ExtraSolar Planets 1/10 Part I: Exoplanet Radial Velocity Simulator Introduction Open up the exoplanet radial velocity simulator. You should note that there are several distinct
panels: •
a 3D Visualization
panel in the upper left where you can see the star and the planet
(magnified considerably). Note that the orange arrow labeled earth view
shows the
perspective from which we view the system. o
The Visualization Controls
panel allows one to check
show multiple views
. This
option expands the 3D Visualization panel so that it shows the system from three
additional perspectives: •
a Radial Velocity Curve
panel in the upper right where you can see the graph of radial
velocity versus phase for the system. The graph has show theoretical curve
in default
mode. A readout lists the system period
and a cursor allows one to measure radial
velocity and thus the curve amplitude
(the maximum value of radial velocity) on the
graph. The scale of the y-axis renormalizes as needed and the phase of perihelion (closest
approach to the star) is assigned a phase of zero. Note that the vertical red bar indicates
the phase of the system presently displayed in the 3D Visualization panel. This bar can be
dragged and the system will update appropriately. •
There are three panels which control system properties. o
The Star Properties
panel allows one to control the mass of the star. Note that the
star is constrained to be on the main sequence – so the mass selection also
determines the radius and temperature of the star. o
The Planet Properties
panel allows one to select the mass of the planet and the
semi-major axis and eccentricity of the orbit. o
The System Orientation
panel controls the two perspective angles.
Inclination
is the angle between the Earth’s line of sight and the plane of
the orbit. Thus, an inclination of 0º corresponds to looking directly down
on the plane of the orbit and an inclination of 90º is viewing the orbit on
edge.
Longitude
is the angle between the line of sight and the long axis of an
elliptical orbit. Thus, when eccentricity is zero, longitude will not be
relevant. •
There are also panels for Animation Controls
(start/stop, speed, and phase) and Presets
(preconfigured values of the system variables). NAAP – ExtraSolar Planets 2/12
Exercises Select the preset labeled Option A and click set. This will configure a system with the following
parameters – inclination: 90º, longitude: 0º, star mass: 1.00 M
sun
, planet mass: 1.00 M
jup
,
semimajor axis: 1.00 AU, eccentricity: 0 (effectively Jupiter in the Earth’s orbit). Question 3:
Describe the radial velocity curve. What is its shape? What is its amplitude? What is
the orbital period
? The radial velocity curve indicates how fast a star is moving around the
center of mass. It is a horizontal S shape with an amplitude of 28 and it orbits for a year. Increase the planet mass to 2.0 M
jup
and note the effect on the system. Now increase the planet
mass to 3.0 M
jup
and note the effect on the system. Question 4:
In general, how does the amplitude of the radial velocity curve change when the
mass of the planet is increased? Does the shape change? Explain. When the planet mass
increases, the amplitude increases. When the planet is larger, the center of mass moves closer to
the planet. Return the simulator to the values of Option A. Increase the mass of the star to 1.2 M
sun
and note
the effect on the system. Now increase the star mass to 1.4 M
sun
and note the effect on the system.
Question 5:
How is the amplitude of the radial velocity curve affected by increasing the star
mass? Explain. When you increase the star mass, the amplitude of the radial velocity curve
decreases. NAAP – ExtraSolar Planets 3/12
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Return the simulator to the values of Option A. Question 6:
How is the amplitude of the radial velocity curve affected by decreasing the
semimajor axis of the planet’s orbit? How is the period of the system affected? Explain. When the semi-major axis of the planet’s orbit decreases, the amplitude of the radial velocity curve increases. The period of the system decreases when you decrease the semi-
major axis of the planets orbit. Return the simulator to the values of Option A
so that we can explore the effects of system
orientation. It is advantageous to check show multiple views
. Note the appearance of the system
in the earth view
panel for an inclination of 90º. Decrease the inclination to 75º and note the effect on the system. Continue decreasing inclination
to 60º and then to 45º. Question 7:
In general, how does decreasing the orbital inclination affect the amplitude and shape
of the radial velocity curve? Explain
. It affects the amplitude because when you decreases the
inclination it decreases the amplitude of the radial velocity curve and it makes the shape more
circular. Question 8:
Assuming that systems with greater amplitude are easier to observe are we more
likely to observe a system with an inclination near 0° or 90°. Explain. A system with an inclination of 90 degrees is more likely to be observed because it has a greater amplitude than one with a system near 0 degrees.
NAAP – ExtraSolar Planets 4/12
Return the simulator to Option A. Note the value of the radial velocity curve amplitude. Increase
the mass of the planet to 2 M
Jup
and decrease the inclination to 30°. What is the value of the radial
velocity curve amplitude? Can you find other values of inclination and planet mass that yield the
same amplitude? Question 9:
Suppose the amplitude of the radial velocity curve is known but the inclination of the
system is not. Is there enough information to determine the mass of the planet
? No, there isn’t
enough information to determine that. Question 10:
Typically astronomers don’t know the inclination of an exoplanet system. What can
astronomers say about a planet's mass even if the inclination is not known? Explain. Astronomers can still determine its minimum mass through the Doppler spectroscopy method
. Select the preset labeled Option B
and click set
. This will configure a system with the following
parameters – inclination: 90º, longitude: 0º, star mass: 1.00 M
sun
, planet mass: 1.00 M
jup
,
semimajor axis: 1.00 AU, eccentricity: 0.4. Thus, all parameters are identical to the system used
earlier except eccentricity. In the orbit view box below indicate the earth viewing direction. Sketch the shape of the radial
velocity curve in the box at right. NAAP – ExtraSolar Planets 5/12
Now set the longitude to 90°. Again indicate the earth’s viewing direction and sketch the shape
of the radial velocity curve. Question 12:
Describe what the longitude parameter means. Does longitude matter if the orbit is
circular? Longitude parameter affects the radial velocity curve. Longitude does not matter if the orbit is circular.
NAAP – ExtraSolar Planets 6/12
Question 11:
Does changing the longitude affect the curve in the example above?
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Select the preset labeled HD 39091 b
and click set
. Note that the radial velocity curve has a
sharp peak. Question 13:
Determine the exact phase at which the maximum radial velocity occurs for HD
39091 b. Is this at perihelion? Does the minimum radial velocity occur at aphelion? Explain. (Hint: Using the show multiple views
option may help you.) The maximum radial velocity occurs at phase 0.0. Yes, this is at perihelion. The min. radial velocity does occur at aphelion.
This simulator has the capability to include noisy radial velocity measurements. What we call
‘noise’ in this simulator combines noise due to imperfections in the detector as well as natural
variations and ambiguities in the signal. A star is a seething hot ball of gas and not a perfect light
source, so there will always be some variation in the signal. Select the preset labeled Option A
and click set
once again. Check show simulated
measurements
, set the noise to 3 m/s, and the number of observations to 50. Question 14:
The best ground-based radial velocity measurements have an uncertainty (noise) of
about 3 m/s. Do you believe that the theoretical curve could be determined from the
measurements in this case? (Advice: check and uncheck the show theoretical curve
checkbox
and ask yourself whether the curve could reasonably be inferred from the measurements.) NAAP – ExtraSolar Planets 7/12
Explain. Yes, the theoretical curve could be determined from the measurements. Select the preset labeled Option C
and click set
. This preset effectively places the planet
Neptune (0.05 M
Jup
) in the Earth’s orbit. Question 15:
Do you believe that the theoretical curve shown could be determined from the
observations shown? Explain
. No, the theoretical curve could not be determined from the
observations because they do not follow the curve. Select the preset labeled Option D and click set. This preset effectively describes the Earth
(0.00315 M
Jup
at 1.0 AU). Set the noise to 1 m/s. Question 16:
Suppose that the intrinsic noise in a star’s Doppler shift signal – the noise that we
cannot control by building a better detector – is about 1 m/s. How likely are we to detect a planet
like the earth using the radial velocity technique? Explain. The radial velocity technique is an
effective method for location planets so it is very likely that we would be able to detect a planet
by using it. NAAP – ExtraSolar Planets 8/12
You have been running an observing program hunting for extrasolar planets in circular orbits
using the radial velocity technique. Suppose that all of the target systems have inclinations of
90°, stars with a mass of 1.0 M
sun
, and no eccentricity. Your program has been in operation for 8
years and your equipment can make radial velocity measurements with a noise of 3 m/s. Thus,
for a detection to occur the radial velocity curve must have a sufficiently large amplitude and the
orbital period of the planet should be less than the duration of the project (astronomers usually
need to observe several cycles to confirm the existence of the planet). Use the simulator to
explore the detectability of each of the following systems. Describe the detectability of the planet
by checking Yes, No, or Maybe. If the planet is undetectable, check a reason such as “period too
long” or “amplitude too small”. Complete the following table. Two examples have been
completed for you. Mass (M
Jup
) Radius (AU) Amplitude (m/s) Period (days) Detectable Y N M Rationale A too P too small big 0.1 0.1 8.9 11 X 1 0.1 90 11.5 x 5 0.1 445 11.5 x 0.1 1 2.78
365
x x 1 1 28.8
365 x 5 1 142.5
364 x 0.1 5 1.25 4080 x
x
x
1 5 13.02 4080 x x 5 5 63.4 4070 X X 0.1 10 .86 4070 x x 1 10 9.1
11,500 x x
5 10 45.6
11,500 x
x
Question 17:
Use the table above to summarize the effectiveness of the radial velocity technique. What types of planets is it effective at finding? Planets are detected easier when the radius is low. The higher the radius, the less detectable they are. NAAP – ExtraSolar Planets 9/12
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Part II: Exoplanet Transit Simulator Introduction Open the exoplanet transit simulator. Note that most of the control panels are identical to those in
the radial velocity simulator. However, the panel in the upper right now shows the variations in
the total amount of light received from the star. The visualization panel in the upper left shows
what the star’s disc would look like from earth if we had a sufficiently powerful telescope. The
relative sizes of the star and planet are to scale in this simulator (they were exaggerated for
clarity in the radial velocity simulator.) Experiment with the controls until you are comfortable
with their functionality. Exercises Select Option A and click set. This option configures the simulator for Jupiter in a circular orbit
of 1 AU with an inclination of 90°. Question 18:
Determine how increasing each of the following variables would affect the depth and duration of the eclipse. (Note: the transit duration is shown underneath the flux plot.) Radius of the planet: When you increase the radius of a planet, it increases the hours of duration in the eclipse. Semimajor axis: The eclipse increases with the semimajor increases. NAAP – ExtraSolar Planets 10/12
Mass (and thus, temperature and radius) of the Star: The eclipse shortens when mass increases.
Inclination: There is no eclipse if inclination is changed. The Kepler space probe (http://kepler.nasa.gov, scheduled for launch in 2008) will attempt to
photometrically detect extrasolar planets during transit. It is predicted to have a photometric
accuracy of 1 part in 50,000 (a noise of 0.00002). Question 19:
Select Option B
and click set
. This preset is very similar to the Earth in its orbit.
Select show simulated measurements and set the noise to 0.00002. Do you think Kepler will be
able to detect Earth-sized planets in transit
? Yes, Kepler will be able to detect Earth-sized
planets. Question 20:
How long does the eclipse of an earth-like planet take? How much time passes
between eclipses? What obstacles would a ground-based mission to detect earth-like planets
face? The eclipse is about 13.1 hours long and the time between them is about one year. Obstacles include cloud coverage, pollution, and reduced visibility in the atmosphere. NAAP – ExtraSolar Planets 11/12
NAAP – ExtraSolar Planets 12/12
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