Galaxy Types, the Big Bang, the Sun and Moon's effects on the Earth

Question 1

The brightness and color of a star depend on its ___________________.

Answer 1

surface temperature

[Explanation]

The hottest stars are blue, moving down the spectrum to the coolest stars, which are red.

Question 2

The surface temperature may determine the brightness and color of a star, but the surface temperature itself is basically determined by the star’s ______.

Answer 2

mass

[Explanation]

Given the mass of a star, we can tell a star’s radius, luminosity and temperature. You can see this in the graphic below–the least massive stars are in the lower right, and as they move towards the upper-left on the main sequence, they’re getting not only bigger, but hotter and brighter at the same time. Mass is really what determines a star’s position on the main sequence.

To summarize (for stars in the main sequence):

• More mass means higher temperature
• More mass means higher luminosity
• More mass means bigger

Question 3

Because a star’s mass determines how much fuel it has to burn and how fast it will burn that fuel, a star’s mass also determines the _______ of a star.

Answer 3

lifetime

[Explanation]

How long a star will spend on the main sequence is dependent on its mass, because a mass determines a) how much fuel a star has to burn b) how quickly it burns that fuel (luminosity). Note that luminosity increases much faster than mass, so a star that’s half as massive as our Sun is only 1/10 as bright. A star that’s ten times as
massive as our Sun would be thousands of times brighter.

This also means that the more massive a star, the faster it burns through its fuel and exits the main sequence. A star of one solar mass (i.e. our sun) is estimated to have a lifespan of 10 billion years on the main sequence while a massive supergiant may only last a few million years.

Question 4

A star is on the main sequence as long as it has enough ________ to burn.

Answer 4

hydrogen

[Explanation]

A star becomes a main sequence star once it starts nuclear fusion. Basically, during its lifetime, a main sequence star is sitting there converting hydrogen to helium through nuclear reactions–the mass that’s left over from these reactions escapes as electromagnetic radiation–light (and heat). When a star exhausts most of its core hydrogen supply, that’s when it leaves the main sequence and becomes a red giant.

Question 5

_____ are born in molecular clouds, dense clouds of gas and dust.

Answer 5

Stars

[Explanation]

A molecular cloud, sometimes referred to as a stellar nursery, is usually seen as a nebula of high density.

Question 6

Over time, the hydrogen in this cloud or a particularly dense portion of the cloud collapses and compacts due to its own gravity. As it compacts, it heats up, eventually forming a large and compartively cool mass of gas known as a _________.

Answer 6

protostar

[Explanation]

A protostar is the stage before becoming an actual star. If it’s too small, it may never become an actual star, instead becoming a brown dwarf.

Question 7

For a protostar to become an actual star, it must have enough mass to reach about ___ million degrees celsius, at which nuclear fusion of hydrogen begins.

Answer 7

10

[Explanation]

It is once this nuclear reaction begins to turn hydrogen into helium that the protostar has become an actual “main sequence” star. As you learned, where it is on the main sequence will be determined by its mass.

Question 8

When compared to Earth’s Sun, which of the following is larger and colder?

 ( ) Red Dwarf
 ( ) Red Giant 
 ( ) Blue Giant 
 ( ) White Dwarf 
 ( ) Black Dwarf

Answer 8

Red Giant

[Explanation]

A red giant is dark red because it is much cooler than it was as a main sequence star, but due to its sheer size, it’s more luminous. Red giants are tens to hundreds of times larger than our sun. In contrast, blue giants are large (5 - 10 times the radius of the Sun ) but much hotter.

Question 9

Once the star has converted just about all of the hydrogen in its core into helium, the core starts to ________. The core will keep compressing until it reaches a temperature and density that is high enough to begin the fusion of helium to form carbon.

Answer 9

collapse

[Explanation]

Meanwhile, while the core is compressing, the outer layers of the star are expanding rapidly. What you end up with is a much bigger star with a much smaller core–a red giant. It is dark red because it is much cooler than it was as a main sequence star, but due to its sheer size, it’s more luminous.

Question 10

1> the hydrogen in a molecule cloud collapses to form a weakly glowing protostar.
2> A protostar collapses until it gets hot and dense enough to start nuclear fusion to begin turning its hydrogen into helium.
3> As soon as this nuclear fusion begins, the core stops collapsing and stabilizes–it is now a _____________ star.

Answer 10

main sequence

[Explanation]

Some protostars don’t have enough mass to ever reach the 10 million Celsius required for nuclear fusion to start. These little protostars end up becoming brown dwarfs instead–too big to be a planet and too small to be a star.

Question 11

Question 11 of 33

To continue with the summary:
4> the main sequence star burns until it’s used up all of the hydrogen in its core.
5> Once the hydrogen in the core has all been converted into a core of helium, the ______________ stops. As a result, the core destabilizes and resumes its collapse.

Answer 11

nuclear fusion

[Explanation]

The core of a star maintains its stability only while nuclear fusion is going on to counter the pressure of gravity. If there’s no nuclear fusion, then the core is going to keep compressing until it gets hot and dense enough for nuclear fusion to occur.

Question 12

Now that the star is no longer burning hydrogen, its time as a main sequence star is done. Continuing with the sequence:
6> While the core is collapsing, the outer envelope is expanding rapidly.
7> Once the core collapses enough, the pressure is great enough to start up nuclear fusion to change the helium into carbon. Once this nuclear fusion starts, the core is stable again and now you have a red giant.
8> Of course, eventually, the red giant will burn through all of its helium, and what happens at that point is going to depend on the ____ of the star.

Answer 12

mass

[Explanation]

Generally, at this stage, stars are split into low-mass stars and high-mass stars. Low mass stars and high-mass stars are born the same way and go through the same steps up to the red giant stage (high-mass stars just go through the steps much quicker), but after the red giant stage, their paths diverge.

Question 13

If it’s a low-mass star, the red giant’s core will collapse into a tiny, hot and superdense core while it sheds the outer layers into a beautiful planetary nebula. At this point, the red giant has become a ___________.

Answer 13

white dwarf

[Explanation]

A white dwarf is so dense that it’s considered to be one of the densest forms of matter in the universe, surpassed only by neutron stars. Although it’s hot and superdense, it’s not very luminous because it’s so small. The white dwarf is a dying star in its final stages–it has no source of energy so it may start out very hot when it’s initially formed, but it will gradually radiate away all of its heat and cool down.

Question 14

A white dwarf will eventually cool to a point where it’s just a dead lump of carbon in space–a ___________.

Answer 14

black dwarf

[Explanation]

It’s unknown if any black dwarves actually exist–scientists speculate that the universe probably isn’t old enough yet for any white dwarves to have finished cooling off and dying.

Question 15

In high-mass stars, the red giant (technically a red supergiant) doesn’t become a white dwarf. Yes, its core of carbon starts contracting, but it’s so massive that as it contracts, it can cause further nuclear reactions, converting carbon into oxygen, neon, silicon, sulphur, and finally to ____.

Answer 15

iron

[Explanation]

The more mass a star has, the higher the gravitational pressure in its core. Most stars can’t generate enough pressure to burn carbon–that’s why once their core is converted into carbon, they turn into white dwarves and die.

With a high-mass star, it keeps undergoing successive nuclear reactions, each time forming a heavier and heavier element until finally it ends with iron. Iron is the most stable element and there is no energy to be gained from converting it into a heavier element.

Question 16

Once the core of a red supergiant is essentially all ____, the core collapses even further and what you get is a mighty explosion known as a supernova.

Answer 16

iron

[Explanation]

Right before the fully mature red giant explodes in a supernova, it has the structure of an onion. That’s because each nuclear reaction produces a heavier element which sinks to the center, becoming fuel for the subsequent reaction. As you can see in the diagram below, the end result is a core of iron (Fe):

Question 17

Supernovas are important because they result in the release of many exotic “_______” elements.

Answer 17

heavier

[Explanation]

Supernovas are extremely powerful; during a month they outshine their entire galaxy and radiate more energy than our sun will over its entire lifespan. This energy is high enough that as it is exploding outwards it creates many elements which are heavier than iron.

Without supernovas, many of the elements necessary to life as we know it would not exist. On a side note, supernovas release an abundance of X-rays and gamma-rays.

Question 18

Most of the time, it doesn’t end with the supernova. If the core that’s left after the explosion is small (i.e. less than 3 solar masses), then it will become a ____________.

Answer 18

neutron star

[Explanation]

A neutron star is the densest form of matter to exist. Note that a neutron star that’s rapidly spinning is a pulsar–it pulses because as it’s rotating, each time its magnetic poles align with the Earth, we receive a pulse of radiation. Typically that radiation is in the form of radio waves, although some have been known to emit X-ray and gamma ray pulses.

Question 19

If the ____ that’s left after a supernova is big (i.e. greater than 3 solar masses), then it will become a black hole.

Answer 19

core

[Explanation]

A black hole is the most compact object imaginable–hypothetically so compact and having so much gravitational force that nothing can escape it–not even light. Note that very rarely, the supernova is so strong that neither a neutron star nor a black hole is formed–essentially the entire core is destroyed.

Question 20

Which of the following is described as a star in its earliest observable phase of development?

 ( ) White Dwarf
 ( ) Red Giant 
 ( ) Blue Giant 
 ( ) Main Sequence 
 ( ) Protostar

Answer 20

Protostar

[Explanation]

Over time, the hydrogen in a molecular cloud or a particularly dense portion of the cloud collapses and compacts due to its own gravity. As it compacts, it heats up, eventually forming a large and compartively cool mass of gas known as a Protostar.

Question 21

When compared to Earth’s Sun, a White Dwarf is much ______ and less luminous.

Answer 21

denser

[Explanation]

A white dwarf is so dense that it’s considered to be one of the densest forms of matter in the universe, surpassed only by neutron stars. Although it’s hot and super dense, it’s not very luminous because it’s so small.

Question 22

A black hole consists of two parts–at the center would be a ___________ and “surface” of the black hole would be the event horizon.

Answer 22

singularity

[Explanation]

A singularity is an infinitesimally small point with infinite density, exerting infinitely strong gravitational force.

Question 23

Which of the following is the approximate age of the Solar System?

 ( ) 39 Billion Years 
 ( ) 85 Billion Years 
 ( ) 4.6 Billion Years 
 ( ) 8.5 Million years
 ( ) 43 Million Years

Answer 23

4.6 Billion Years

[Explanation]

By studying meteorites, and using radioactive dating techniques, scientists have determined that the Solar System is 4.6 billion years old.

Question 24

The density of ______________ on a planetary surface can be used as a measure of the age of that surface.

Answer 24

impact craters

[Explanation]

Surfaces with relatively few craters are young, while surfaces with many craters are old.

Question 25

The age of the solar system is determined from the study of

 ( ) Pulsars 
 ( ) Black holes
 ( ) Asteroids 
 ( ) Meteorites 
 ( ) Quasars

Answer 25

Meteorites

[Explanation]

Scientists estimate the age and bulk chemical composition of the Solar System and the order in which different components in meteorites and the Solar System formed, by measuring the amounts of various elements in meteorites. Meteorites are among the oldest objects known, formed approximately 4.6 billion years ago. Scientists determine the ages of very old objects (example meteorites) by measuring the decay products of radioactive isotopes using a process called radiometric dating.

Question 26

An _____________ is described as the boundary within which the black hole’s escape velocity is greater than the speed of light.

Answer 26

event horizon

[Explanation]

A black hole is a large mass contracted to extremely small size and enormous density. The surface of a black hole, or the boundary through which no light can get out, is called the event horizon.

Question 27

Astronomers call all elements heavier than ________ and helium metals.

Answer 27

hydrogen

[Explanation]

Therefore, when we refer to the metallicity of an object, we are talking about what percentage of it is composed of heavier elements–elements other than Hydrogen and Helium.

Question 28

Which of the following can be formed when very massive stars supernova and collapse at the end of their life cycle?

 ( ) Planetoids 
 ( ) Protostars 
 ( ) Black Holes 
 ( ) Fermionic particles 
 ( ) Asteroids

Answer 28

Black Holes

[Explanation]

If the core that’s left after a supernova is big (i.e. greater than 3 solar masses), then it will become a black hole. A black hole is a large mass contracted to extremely small size and enormous density. It is generally believed that super massive black holes exist in the centers of most galaxies.

Question 29

Which of the following is described as an extremely dense star formed from the remnants of a massive star’s gravitational collapse and supernova?

 ( ) Protostar 
 ( ) Black Dwarf
 ( ) Red Giant 
 ( ) Variable Star 
 ( ) Neutron Star

Answer 29

Neutron Star

[Explanation]

If the core that’s left after a Supernova is small (i.e. less than 3 solar masses), then it will become a Neutron Star. Neutron stars are made mostly of neutrons, uncharged atomic particles. A neutron star is the densest form of matter to exist. Note that a neutron star that’s rapidly spinning is a pulsar–it pulses because as it’s rotating, each time its magnetic poles align with the Earth, we receive a pulse of radiation.

Question 30

The ___________ of a star may correlate with its age.

Answer 30

metallicity

[Explanation]

Based on the Big Bang theory, the early universe should have been composed entirely of Hydrogen and Helium. The heavier elements would have been produced later in the first stars and distributed through their supernovas.

Question 31

The Population system of classifying stars is based on its metallicity. Population III stars are the ______, with the lowest metallicity.

Answer 31

oldest

[Explanation]

Astronomers break down stars into three categories: Population I, II, and III, with Population III being the oldest. A population III star has no metallicity–it would be one of the first stars formed after the Big Bang, composed entirely of Hydrogen and Helium. Population III stars are actually hypothetical–none have ever been observed.

Question 32

The oldest stars that have been found in the universe are Population __ stars.

Answer 32

II

[Explanation]

A Population III star has never been found. Population II stars have very low metal content, but even the oldest Population II star has at least a little bit of metal (around 0.1%). Population II stars tend to be found in globular clusters and in the halos of galaxies. They are less luminous and cooler than Population I stars.

Question 33

The ________ stars are the Population I stars, and these tend to be found in open clusters.

Answer 33

youngest

[Explanation]

Open clusters are young, and therefore consist of the young Population I stars. Population I stars have the highest metallic content. Based on what you learned about the Big Bang, how stars our formed, and supernovas, this makes sense.

The earliest stars would have been formed entirely of hydrogen and helium. When they blew up in supernovas, they would have created and left behind heavier elements–metals. New stars that formed in these clouds of gas from the aftermath of the supernova would have higher metallic content, and when they explode, they would leave behind an even richer cloud of gas for subsequently born stars.

In other words, each generation of stars would be more metallic than the previous one. Our sun is a population I star.