LB3
lab5.mp4_(HD_720_-_WEB_(H264_2500))-20211025_023315
0:12 Hello again, welcome to Lab 5.
0:15 Just letting you know right off
0:16 the bat this is going to be way
0:18 easier than the previous lab.
0:19 Barely any math.
0:20 There's an Excel plotting, but it's
0:21 not nearly going to be as complicated,
0:23 which means that the editing is going
0:25 to be way less stressful on my end.
0:27 There was almost 50 minutes of footage
0:28 in the last video that I made and it took
0:31 me three or four hours to edit that.
0:33 And then it took another six hours
0:35 with dealing with icollege ********
0:37 in order to get it to upload,
0:38 so hopefully that won't happen this week.
0:41 The gist of this lab is that you will be
0:43 measuring a distance using one of the
0:45 rungs of the cosmic distance ladder,
0:47 which we'll get to in a couple of labs.
0:49 This one is just really well known.
0:50 It deals with the topic of stellar
0:52 evolution that you've hopefully
0:53 gotten to in your lecture.
0:54 But besides parallax,
0:55 the way that we measure distance
0:57 in astronomy has to do with
0:59 two fundamental concepts.
1:00 The first is the magnitude system,
1:02 where a little M is the apparent
1:03 magnitude of an object.
1:05 It is the apparent brightness of
1:06 something how we measure it on Earth.
1:07 And then there's capital M.
1:10 No one likes this notation.
1:11 The only thing different is that
1:13 one is capital and one is not.
1:14 So the difference is capital M
1:16 is the absolute magnitude or the
1:18 intrinsic brightness of something.
1:19 If you were to go right up to it,
1:20 how bright would it be?
1:21 And you compare apples to apples to
1:23 always measure things to the same scale.
1:25 The absolute magnitude is the
1:27 brightness of something that's
1:28 measured at a distance of 10 parsecs.
1:29 Remember what a parsec is?
1:31 1 parsec is 3.26 light years.
1:34 The reason why we get this number is
1:36 that one parsec is the distance that
1:38 some celestial object would have to be
1:41 to have a parallax angle of 1 arcsecond.
1:43 So parallax arcsecond?
1:45 Parsec that distance is 3.26 light years.
1:47 Using these two things tells us
1:49 what the distance must be and I'll
1:50 write the equation in just a second.
1:52 But conceptually it makes sense
1:53 if we measure the brightness of
1:55 something as it appears on Earth and
1:56 we know how bright it actually is,
1:58 then the farther apart those two numbers are,
2:01 the greater the distance must be.
2:02 If they were the same number,
2:03 that means that we're right next
2:05 to the object.
2:05 The further apart they are in value,
2:08 the further away the object must be.
2:09 So the difference between those two m - M.
2:12 So this quantity here is referred
2:14 to as the distance.
2:15 Modulus and the distance modulus
2:17 equation is m - m = 5 log d - 5.
2:23 So the difference between these two
2:25 objects on a log scale gives us what?
2:28 The distance must be and this distance
2:30 is always measured in parsecs.
2:31 The thing with this so if we want
2:33 to measure
2:33 distance to objects that are
2:34 farther away from something that we
2:36 can measure easily with parallax,
2:37 we can always measure what the
2:38 apparent magnitude is. On earth.
2:39 It's much much harder to measure
2:41 the absolute magnitude of something,
2:42 because we're not next to it.
2:44 We can't make a measurement of something
2:45 at 10 parsecs if we're not at 10 parsecs.
2:47 So what we have to do,
2:48 what the whole distance ladder concept
2:50 means is find something that gives
2:52 us absolute magnitude so that we can
2:54 compare to the brightness on earth so
2:56 that we can constrain the distance.
2:58 That's the that's the basic concept.
3:00 One of the best,
3:00 easiest ways to do that for things
3:02 in the local universe,
3:03 including other galaxies,
3:04 is using what are known as C feed
3:07 variable stars.
3:08 Hopefully you've touched on this in lecture.
3:10 If not, I'll go over really quickly.
3:12 What is a variable star?
3:13 Well, the first question we want to
3:15 ask is how do stars normally work?
3:16 You have a core that's producing
3:19 fusion that's emitting a bunch
3:21 of radiation pressure.
3:22 All the while the entire mass of
3:24 this thing is made of is always.
3:26 Pushing inwards so this is the force
3:28 of gravity and the reason why stars
3:31 keep their shape is because the force
3:33 of gravity is equal to the force.
3:36 The force of gravity is equal to
3:37 the force of radiation pressure.
3:38 The amount of radiative force
3:40 that the core is pushing out from
3:42 nuclear fusion is matched exactly
3:44 by the force of gravity.
3:45 Wanting to crush everything
3:46 in this is how our son works.
3:48 This is how most stars work.
3:50 The thing with variable stars
3:51 is that this isn't the case.
3:53 You have a mismatch between the
3:54 amount of force the gravity has
3:55 in the amount of force that the
3:57 radiation pressure has.
3:58 So let's say at step one by variable
4:00 star is producing more radiation pressure
4:02 than it is gravitational pressure,
4:04 so.
4:04 This here is way more powerful than
4:07 the force of gravity pushing it inward.
4:09 So here my radiation pressure is
4:11 more than my my force of gravity.
4:13 That means that things pushing outward
4:14 are stronger than things pushing inward,
4:16 and so this thing it will push
4:18 everything out and so this thing
4:19 will expand it as it expands.
4:21 What happens to a gas when you let it expand?
4:23 It cools off that gets less dense,
4:25 and the radiation the photons have an
4:27 easier time getting out of the atmosphere.
4:30 So this thing starts to cool off.
4:31 The radiation pressure goes down,
4:32 which means that it starts to collapse again,
4:34 this time gravity.
4:35 Starts to win,
4:36 and so the star shrinks back down.
4:38 And what happens when you compress a gas?
4:40 The pressure goes up,
4:41 the temperature goes up,
4:42 which means that the radiation pressure
4:43 that the core is causing from nuclear fusion.
4:46 If you're upping the pressure and
4:47 you're upping the temperature,
4:48 you're increasing the amount
4:49 of nuclear fusion in the core,
4:51 and so this thing starts to heat
4:53 up and the
4:54 force of radiation.
4:55 Get stronger than gravity again and
4:57 the star starts to expand out and
4:59 then this whole cycle begins again.
5:00 The way that we observe this.
5:02 Like usually we can't see how big stars are.
5:04 We can just see how bright they are.
5:06 So if we were observing
5:08 variable stars overtime,
5:09 if we go from here to here,
5:11 the star has gotten bigger and the
5:13 photons have an easier time getting out
5:15 so the luminosity goes up in this step
5:18 and then as it starts to cool off in,
5:20 the temperature goes down and
5:21 the star compresses again,
5:22 the luminosity goes down.
5:23 You can press the gas it gets,
5:25 it goes up in temperature.
5:26 The radiation pressure starts to increase,
5:28 which means that the star
5:29 starts to expand again,
5:30 which means luminosity goes up.
5:32 It compresses the luminosity goes down,
5:33 and so over time,
5:34 not only is the star changing
5:36 its temperature and its size,
5:37 the luminosity of the star
5:39 is changing over time,
5:40 and so we were to observe a variable
5:42 star over a long period of time and plot
5:44 what's happening to its luminosity.
5:45 It'll start to look something like this.
5:48 Overtime, luminosity goes up,
5:49 the star cools off,
5:51 and it shrinks down,
5:52 so the luminosity goes down,
5:54 increase the radiation pressure it goes up,
5:56 and then it starts to cool down and compress.
5:58 And Luminosity goes back down again.
6:01 But the reason why this applies to distances?
6:04 Because this behavior is related to
6:05 how bright the stars intrinsically are,
6:07 the absolute magnitude depends on this.
6:09 If we measure the period,
6:11 remember for the last couple of labs,
6:13 the period is how long something
6:14 takes to repeat itself,
6:15 and so if it hits maximum brightness here,
6:17 the period is from here until it
6:19 goes back to where it was before,
6:21 and so this would be one period
6:22 for CP at variable stars,
6:24 which is just a specific kind of
6:25 variable star there period of pulsation.
6:27 So how fast they're shrinking and growing
6:29 is related to how bright they intrinsically.
6:32 Promote we've observed
6:33 perceive variable stars.
6:34 If you have a longer period of pulsation,
6:37 you have a brighter star,
6:38 and so we can't ever
6:40 measure absolute magnitude.
6:40 But we can measure the period, right?
6:42 We just have to observe a star for
6:44 a long period of time and then just
6:45 measure how long it takes to get
6:47 back to the beginning of the cycle.
6:48 And so this is telling us if
6:50 you observe the period,
6:51 then you can just use this relationship to
6:53 get what the absolute magnitude that star is,
6:56 because every different period is related
6:58 to a uniquely different absolute magnitude.
7:01 Which means if we measure
7:02 one specific period.
7:03 This relationship tells us what
7:05 the absolute magnitude is,
7:06 and that's all we were looking
7:07 for in the first place.
7:08 We want absolute magnitude
7:09 to measure the distance.
7:10 We can't measure it directly,
7:12 but this thing tells us if
7:13 we measure the period,
7:14 we can get the absolute magnitude
7:15 from this relation,
7:16 plug it into the distance modulus
7:17 and get the distance that way.
7:19 OK,
7:19 so part one table when you're given
7:21 the apparent magnitude of four
7:22 different stars in the same star
7:24 cluster and using their distance,
7:25 you're going to calculate their
7:27 absolute magnitudes.
7:27 So for each one of these stars,
7:28 the distance is 2600 parsecs.
7:30 So for all four of those stars,
7:32 you're going to use this same distance.
7:34 Using this equation and equals
7:36 m + 5 - 5 log D if you're using
7:40 a scientific calculator.
7:41 This is log base 10.
7:42 If you're not using a scientific
7:44 calculator and you have no idea
7:45 what the **** I just said,
7:46 don't worry about it.
7:47 If you to do the do the log something
7:48 to the logarithm of something,
7:50 just type it into your phone and
7:51 then hit the log button.
7:52 If you tip your phone sideways
7:53 and whatever that number is,
7:55 that's the log of whatever
7:56 you're plugging in the table.
7:57 One will have four stars where you
7:59 have the absolute magnitudes and then
8:01 table two table two will give you
8:02 seven additional stars where it's
8:04 already calculated the absolute magnitude.
8:05 For you,
8:06 but in table one and table to you
8:08 also have their periods the log P,
8:10 which is just the logarithm of the period.
8:11 Again type it in your phone,
8:13 take the log and that will give
8:14 you the log
8:15 of the period and So what you're going
8:16 to do is you're going to take all the
8:17 values from table one and table two,
8:19 so 11 total stars and you're going to
8:22 plot log P versus absolute magnitude.
8:24 So the period versus absolute magnitude
8:27 in Excel or pages or whatever
8:29 spreadsheet software that you're using,
8:31 and then construct your own
8:33 period luminosity relationship.
8:34 And I'll show you how to do that right now.
8:36 OK, so here I've copied.
8:37 Over all of the data from table two,
8:39 and then I'm going to use that as
8:40 the example because I don't want to
8:42 give you the answers from table one
8:43 just to let you know you will also
8:45 have the data from table one here
8:47 and so you will have 11 total data
8:49 points in your graph for Part 2.
8:51 So what you're going to do is you're
8:54 going to select the log P&M columns,
8:56 so click this, hold shift click, see.
8:58 So you have both of these highlighted.
9:01 Click on insert,
9:02 go to recommended charts and
9:05 then click on scatter.
9:07 OK, so here is our rough graph here.
9:10 You can make it a little bigger if
9:12 you want to just make it clearer
9:13 we should click on your graph,
9:14 make sure chart design is selected,
9:16 click on add chart elements axis
9:19 titles and then primary horizontal.
9:22 And probably very vertical.
9:23 So that both of these now pop up here,
9:25 the X axis is log P.
9:29 And the Y axis is absolute magnitude.
9:32 Now the last step,
9:32 once our data is here and remember,
9:34 you're going to have four other
9:35 data points from the absolute
9:36 magnitudes that you calculate.
9:38 In part one,
9:38 we're going to draw a trendline that kind
9:40 of best represents what the data is doing.
9:42 So again,
9:43 we're going to go to add chart elements,
9:45 and we're going to go to trendline linear.
9:48 Boom,
9:49 that just happened,
9:51 so hopefully you have something
9:52 that looks like this or I don't
9:54 think I I couldn't find a way in
9:55 pages to flip the axis.
9:56 I know that Excel can do it,
9:58 but I couldn't find a way
9:58 that numbers could do it,
9:59 so I just said yours on your
10:01 spreadsheet will probably look flipped,
10:02 so this is this is fine.
10:04 These values are just mirrored.
10:06 Keep that on your spreadsheet.
10:08 That's something that you're
10:08 going to turn in with your lab so
10:10 that I can see that you did it so
10:11 I can give you credit for it,
10:12 but keep this in mind while
10:13 we move to part three.
10:14 In part three,
10:15 you're going to plot the light curve,
10:17 meaning how much the.
10:18 Brightness of ACV variable
10:20 star is changing over time.
10:22 For one CP had variable in one
10:24 of the satellite dwarf galaxies
10:25 of the Milky Way table.
10:27 Three gives you data points,
10:28 so it gives you time in days and
10:30 it gives you apparent magnitude.
10:32 There are 25 data points there.
10:33 Throw them all into Excel or
10:35 numbers or whatever and
10:36 plot it using the same exact
10:38 way that you plotted the period
10:39 luminosity relation in Part 2.
10:41 Same exact way, same exact directions
10:42 and then once you do that your
10:44 light curve should look something
10:45 like this and I flipped this too,
10:47 so this should actually look like what?
10:49 You guys got in on a mirrored version of it,
10:51 so you should have something
10:52 that looks like this.
10:53 The first thing that you're
10:53 going to want to do,
10:54 the reason why we use CP variables
10:56 in the first place is that we want to
10:58 measure their period of pulsation,
10:59 and so the easiest way I think you can do
11:01 it is go from one peak to the other peak.
11:04 Remember,
11:04 the magnitude scale is always reversed,
11:07 and so if you have 20 up
11:09 here and 10 right here,
11:11 a smaller number of magnitude means brighter,
11:13 and so the peaks of the brightness.
11:14 Or actually the troughs.
11:16 Here I know it's weird anyway,
11:18 so you have a time here.
11:20 So this is time one.
11:21 Of one peak and then the period will
11:23 be how long does it take to get
11:24 back to that same peak brightness
11:26 and that will be over here.
11:27 So just find out what the time is over here.
11:30 T2 the period is just T 2 - T one.
11:34 As your period,
11:35 it's the amount of time between the two
11:37 peaks and then log P is just take this value,
11:39 type it into your calculator,
11:40 hit the log button and that gives you
11:42 your log of the period of pulsation.
11:44 OK,
11:44 the next step is getting the
11:46 absolute magnitude.
11:46 The way to do that is to go back
11:48 to Part 2 where you graphed
11:50 your period luminosity relation.
11:52 When you graph this thing when you have.
11:55 Log P here at M here.
11:57 I think it looks like this for you
11:58 guys anyway, so you calculated log P is.
12:03 You calculated the log P as some number.
12:05 Find that same number down here with
12:06 the graph that you made in Part 2,
12:08 just eyeball go up to the line that
12:10 you drew through all the data points
12:12 and then find what absolute magnitude
12:14 that that log P corresponds to,
12:16 and that's your end. User log P.
12:18 Go up to the line,
12:19 find what absolute magnitude
12:20 that corresponds to for number 5,
12:22 the apparent magnitude the answer is
12:23 going to be the average of all of
12:25 the apparent magnitudes from table three,
12:27 and they're already in Excel,
12:28 so all you have to do is take that
12:30 column and say what is the average of it,
12:32 and that will give you what it is.
12:33 Remember,
12:33 all of them are around 15 something,
12:35 and so the average should also
12:36 be around 15 something and for
12:38 number 6 you're going to take
12:39 that average apparent magnitude,
12:40 and you're going to subtract it
12:42 from the absolute magnitude that
12:44 you got from your graph over here
12:45 and then finally #7 the distance
12:47 just rearranging equation one is 10
12:49 to the power of M minus capital M + 5 / 5.
12:55 This is all in the exponent.
12:57 10 is not multiplied by this 10 is right
12:59 here, and this is all in the exponent,
13:00 so Please remember your PEMDAS do
13:03 everything in the parentheses first,
13:05 then take 10 to the power
13:07 of whatever this thing is.
13:08 It should be between 50,002.
13:13 50,000 to maybe like 80,000
13:15 parsecs or something like that.
13:16 It doesn't have to be exact as long as I can
13:18 see your data and where you got your values.
13:20 As long as you get something near here,
13:23 it's completely fine with me.
13:24 OK, that's about it.
13:25 If you have any questions,
13:27 my office hours are going
13:28 to be the same bat time,
13:29 same bat place Wednesdays and Thursdays.
13:31 One or two PM.
13:32 I tried to make the directions
13:33 as straightforward as possible,
13:35 so hopefully the Excel stuff
13:36 isn't too hard for you guys.
13:38 But anyway happy early October and
13:40 to celebrate the start of the fall.
13:43 Finally, and and the coming of Halloween,
13:46 I figured that for this month,
13:48 besides having bloopers
13:49 at the end of my video,
13:50 I'm just going to show quick clips from
13:52 some of my favorite Halloween movies.
13:54 So enjoy it and I'll see you guys next time.
14:00 Whatever.
14:02 I put on you.
14:10 You