Everything Everywhere Daily: History, Science, Geography & More - Astronomical Distances and the Age of the Universe
Episode Date: September 25, 2022Every so often, astronomers will publish photos taken with an astronomical telescope and say that the object they captured is so many billions of light years away. But how could they know the distan...ce of something from just looking at it? Furthermore, astronomers claim that the universe is almost 14 billion years old. How could they possibly know that? Well, there are answers to these questions, and surprisingly, astronomical distance and age and closely intertwined. Learn more about astronomical distances and the age of the universe on this episode of Everything Everywhere Daily. Subscribe to the podcast! https://link.chtbl.com/EverythingEverywhere?sid=ShowNotes -------------------------------- Executive Producer: Darcy Adams Associate Producers: Peter Bennett & Thor Thomsen Become a supporter on Patreon: https://www.patreon.com/everythingeverywhere Update your podcast app at newpodcastapps.com Discord Server: https://discord.gg/UkRUJFh Instagram: https://www.instagram.com/everythingeverywhere/ Facebook: https://www.facebook.com/EverythingEverywhere Twitter: https://twitter.com/everywheretrip Website: https://everything-everywhere.com/everything-everywhere-daily-podcast/ Everything Everywhere is an Airwave Media podcast." or "Everything Everywhere is part of the Airwave Media podcast network Please contact sales@advertisecast.com to advertise on Everything Everywhere. Learn more about your ad choices. Visit megaphone.fm/adchoices
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Every so often, astronomers will publish photos taken with an astronomical telescope and say that
the object that they captured is so many billions of light years away. But how can they know the
distance of something from just looking at it? Furthermore, astronomers claim that the universe is
almost 14 billion years old, and how could they possibly know that? Well, there are answers to these
questions, and surprisingly, astronomical distance and the age of the universe are closely intertwined.
Learn more about astronomical distances in the age of the universe on this
episode of Everything Everywhere Daily.
What if your perceptions about the past were wrong?
ThruLine is a podcast that takes you back in time to uncover the parts of the story that may
have gone unnoticed.
It effectively turned day into night.
And how it shaped the world now.
Time travel with us every week on the ThruLine podcast from NPR.
In a previous episode, I talked about radiometric dating and how.
researchers can determine the age of plants and birds and rocks and things. What all of those
techniques have in common is that they use the known rate of decay of radioactive elements as a type
of clock to determine the age of something. If you look at the original isotopes ratio to the
element it decays into, you can get an idea of how old something is. The key to this method
is that you need a sample of the thing you want to test. But when it comes to astronomy,
especially very distant objects, we don't have any samples. All we have are observant.
observations and measurements of light. By a similar token, just because astronomers can see an object,
how can they tell how far away something is? As it turns out, the answer to the age of the universe
is tied up in the question of how distant astronomical objects are. To get to the answer to these
questions, we need to climb something called the cosmic distance ladder. Basically, there are different
methods that can be used to determine various distances. So let's start with something pretty easy.
The Moon. We can accurately measure the distance to the moon with an incredible amount of
precision by using the speed of light. Light has a fixed speed when it travels through the vacuum
of space. The fundamental constant is the key to almost every one of the methods I'll be talking
about, because at astronomical distances, light is all we have to work with. To determine the
distance to the moon, you can just bounce light or a radio signal off the moon and determine how
long it takes to come back. You divide that number by two, then multiply by the speed of light to get the
distance. The speed of light is approximately 300,000 kilometers per second or 186,000 miles per second.
There were specifically designed reflectors that were sent to the moon during the Apollo missions,
which are still functioning today. Using those devices, you can measure the distance to the moon
within centimeters. This technique can also be used to bounce radar waves off other bodies in our solar system.
But what about objects further out, like stars?
To measure stars that are reasonably close to Earth, and by reasonably close I mean about 10,000 light years,
you can use a method known as parallax. Parallax basically uses trigonometry to determine distances
by measuring angles and a known distance.
And if you want to experience a version of parallax, you can do that right now.
Hold your thumb out in front of your face with only one eye open.
Notice what your thumb is covering up.
Now, look through your other eye. Try doing this real fast, looking through one eye and then the other.
You'll notice that what your thumb is covering up is slightly different depending on which eye you use.
This is because your eyes are slightly apart and looking at your thumb from a slightly different angle.
That is parallax.
With astronomy, instead of knowing the distance between our eyes, we can use observations at different times of the year,
when the Earth is at one point in its orbit, and six months later, when it's at the opposite point in its orbit.
For stars within the right distance, they will appear to move slightly against the background of stars,
just like your thumb appears to move as you switch your eyes.
If you can measure the angle of the object's apparent change and know the diameter of the Earth's orbit,
then you can calculate the distance to the object.
This has a limit because the further way something gets, the angle gets narrower and narrower.
If the angle is one arc second, which is one 3,600th of a degree, then the distance
is defined as 1 parsec, which is equal to 3.26 light years. And this is extremely handy
information to know if you are planning to do the Kessel run. With better telescopes like the Hubble
or Webb telescope, you can get measurements down to 20 to 40 micro-arc seconds, which allows
you to measure up to 16,000 light years away. 10,000 to 16,000 light years only really lets
us measure our corner of the galaxy, which is a full 100,000 light years.
across. So what about measuring objects further away in the Milky Way? How can we measure those distances?
For that, we need something called a standard candle. One big problem is that you can't tell
how far away a light source is by just looking at the light. It could be a very bright light that's
far away, or a dimmer light that's closer to you. They would appear exactly the same. But if you know
the absolute brightness of something, called its luminosity, then you can measure its observable,
brightness from Earth and determine the difference. Once you know the difference between the
luminosity and the observed brightness, you can calculate the distance with a pretty simple formula.
The most common standard candle is a special type of star known as a sepheid variable.
Seffiate variable stars have a brightness that pulsates. It turns out the luminosity of the star
is tightly correlated to the period it takes to pulsate. Measure the period of the pulse,
you get the luminosity, and then you can measure the apparent brightness here on Earth,
and you got your distance.
If you remember back to my episode on supernovas,
some of them have very unique properties
beyond just being a giant explosion.
A Type 1A supernova only explodes
once it has accreted exactly the right amount of mass
from a neighboring star.
This is known as the Shandra Saker limit.
The fact that all Type 1A supernovas
explode with the exact same amount of mass
means that they all have the exact same luminosity.
Assuming you can find one,
you can then measure its distance.
Depending on the standard candle which is used, you can use this method to measure objects
throughout the entire Milky Way and potentially even some nearby galaxies.
But what about the images which are taken by the web and Hubble telescopes, which claim to show
objects from the edge of the observable universe? How can we measure those distances?
For that, we need something known as Hubble's Law.
Hubble's Law is named after the early 20th century astronomer Edwin Hubble, who discovered
one of the most important fundamental facts in astrophysics.
Galaxies move away from Earth at speeds proportional to their distance.
In other words, the farther away a galaxy is, the faster it's moving away from us.
How do we know that galaxies are moving away from us, and how can we know that more distant
ones are moving faster? This has to do with what is called the red shift.
The red shift is nothing more than the Doppler effect applied to light.
You're probably familiar with the Doppler effect when it comes to sound.
A car will increase its pitch as it approaches you and decrease its pitch as it moves away.
This is because sound is a wave, and when a wave moves towards you, it's compressed,
and when it moves away, it's extended.
In the case of light, instead of changing pitch, it changes color.
Objects moving away will have longer wavelengths of light shifting towards the red part of the spectrum.
Objects moving towards you have shorter wavelengths and are shifted to the light.
the blue part of the spectrum. Because stars are made of hydrogen, remember back to my previous
episode on stars, we know the exact spectrum given off by hydrogen when it glows. By looking at
the hydrogen spectrum, you can see how much it was shifted and measure its velocity. Hubbell's law
states that the velocity of a galaxy equals its distance times a constant. That constant
is known as the Hubble constant. The units of the Hubble constant are kilometers per second
per megaparsec. So, for every million parsecs a galaxy is away, it will be traveling a set number
of kilometers per second faster. The current best estimate for the Hubble constant is 67 kilometers
per second per megaparsec. Now, you might have noted that kilometers and megaparsecs are both units of distance,
and they would actually cancel each other out if you convert the megaparsecs to kilometers,
leaving the actual unit of the constant as the reciprocal of seconds.
And seconds are a unit of time.
So far, all I've been doing is talking about measuring distances,
but at the beginning of this episode, I was talking about the age of the universe.
And this is the point where they come together.
Do a little bit of algebra moving the variables around,
and you get a value that is expressed as a unit of time.
That time is the age of the universe.
A great deal of time and effort has been put into getting
better and better values for the Hubble constant. The most recent effort, called the
Plank Collaboration, measured the cosmic microwave background radiation to get a measurement.
The value they came up with gave an age of the universe of 13,787 million years old,
plus or minus 20 million years. There have been other estimates as well, and they're all within
about 30 million years of each other. This value has been refined over the years, and I would expect
it to get refined even further, as more advances in telescopes.
come online. All of the methods I've mentioned for determining astronomical distances get more accurate
the closer the object is to Earth, which should be expected. So whether or not you realize it,
the size of the universe is intrinsically tied up with the age of the universe, and it's all due to
Hubble's Law, which is one of the most elegant equations in all of science. So the next time you hear
something on the news about an astronomical discovery billions of light years away, know that there is a
method to the madness. And there are techniques developed over the last century, which can measure
both the size and age of our universe. Everything Everywhere Daily is an Airwave Media podcast.
The executive producer is Darcy Adams. The associate producers are Thor Thompson and Peter Bennett.
Today's review comes from listener Irish English teacher over at Podcast Republic. They write,
I teach ESL and often recommend the podcast to my students. I'd like to point out that in Ireland,
we still use ye to distinguish between you singular and plural.
And the accusative, object pronoun, is her, not she.
I am a member of the Completionist Club. Keep up the good work.
Well, thanks, Irish-English teacher.
In the course of researching the episode on Shakespearean English,
I did come across the fact that in Yorkshire,
they do use a form of thou, as do some Quakers who speak in a dialect called plainspeak.
However, I didn't come across anything about the Irish use of yee, which is really interesting.
I never heard it in my various trips to Ireland, but then again I really wasn't in a situation where ye would have been used.
Remember, if you leave a review or send me a boostogram, you two can have it read on the show.
