ASTR 102 Chapter 16- Star Birth

Astronomers estimate that new stars form in our galaxy at the rate of about

A) one per year.

B) a few (2-3) per year.

C) ten per year.

D) 20-30 per year.

E) 100 per year.

B) a few (2-3) per year.

By mass, the interstellar medium in our region of the Milky Way consists of

A) 70% Hydrogen, 30% Helium.

B) 70% Hydrogen, 28% Helium, 2% heavier elements.

C) 70% Hydrogen, 20% Helium, 10% heavier elements.

D) 50% Hydrogen, 50% Helium.

E) 50% Hydrogen, 30% Helium, 20% heavier elements.

B) 70% Hydrogen, 28% Helium, 2% heavier elements.

What percentage of a molecular cloud's mass is interstellar dust?

A) 1%

B) 2%

C) 28%

D) 50%

E) 1-50%, depending on the mass of the molecular cloud

A) 1%

The typical density and temperature of molecular clouds are

A) 100 molecules per cubic centimeter, 10-30 Kelvin.

B) 300 molecules per cubic centimeter, 10-30 Kelvin.

C) 1000 molecules per cubic centimeter, 10-30 Kelvin.

D) 100 molecules per cubic centimeter, 100-300 Kelvin.

E) 300 molecules per cubic centimeter, 100-300 Kelvin.

B) 300 molecules per cubic centimeter, 10-30 Kelvin.

The most abundant molecule in molecular clouds is

A) H2.

B) He2.

C) CO.

D) H2O.

E) HHe.

A) H2.

The typical size of an interstellar dust grain is

A) 1 angstrom.

B) 1 nanometer.

C) 1 micrometer.

D) 1 millimeter.

E) 1 centimeter.

C) 1 micrometer.

What is interstellar reddening?

A) Interstellar dust absorbs more red light than blue light, making stars appear redder than their true color.

B) Interstellar dust absorbs more red light than blue light, making stars appear bluer than their true color.

C) Interstellar dust absorbs more blue light than red light, making stars appear redder than their true color.

D) Interstellar dust absorbs more blue light than red light, making stars appear bluer than their true color.

E) The spectral line shift due to a star's motion through the interstellar medium.

C) Interstellar dust absorbs more blue light than red light, making stars appear redder than their true color.

If you wanted to observe a molecular cloud, in what wavelength of light would you most likely observe?

A) ultraviolet

B) visible

C) infrared

D) X-ray

E) gamma-ray

C) infrared

What happens to the visible radiation produced by new stars within a molecular cloud?

A) It escapes the cloud completely.

B) It is absorbed by dust grains and heats up the cloud.

C) It is reflected back onto the protostar, heating it up further.

D) The blue light is absorbed and the red light transmitted.

E) It shoots out in bright jets.

B) It is absorbed by dust grains and heats up the cloud.

The thermal pressure of a gas depends on

A) density only.

B) temperature only.

C) density and temperature.

D) composition.

E) gravity.

C) density and temperature.

The gravitational force in a molecular cloud depends on

A) density only.

B) temperature only.

C) density and temperature.

D) composition.

E) thermal pressure.

A) density only.

What prevents the pressure from increasing as a cloud contracts due to its gravity?

A) As the cloud becomes denser, gravity becomes stronger and overcomes the pressure buildup.

B) The pressure is transferred from the center of the cloud to its outer edges where it can dissipate.

C) Thermal energy is converted to radiative energy via molecular collisions and released as photons.

D) Excess pressure is released in jets of material from the young stars.

E) Once the cloud reaches a critical density, the pressure becomes degenerate and independent of temperature.

C) Thermal energy is converted to radiative energy via molecular collisions and released as photons.

Calculations show that gravity begins to overcome thermal pressure in clouds that are

A) less massive than the Sun.

B) more massive than the Sun.

C) more massive than ten times the Sun.

D) more massive than a hundred times the Sun.

E) more massive than a thousand times the Sun.

D) more massive than a hundred times the Sun.

What property of a molecular cloud does not counteract gravitational contraction?

A) thermal pressure

B) turbulent motions

C) magnetic fields

D) fragmentation

D) fragmentation

How do astronomers infer the presence of magnetic fields in molecular clouds?

A) by measuring the amount of interstellar reddening

B) by measuring the Doppler shifts of emission lines from gas clumps in the cloud

C) by measuring the infrared light emitted by the cloud

D) by measuring the polarization of starlight passing through the cloud

E) by measuring the amount by which gravity is reduced

D) by measuring the polarization of starlight passing through the cloud

What is the likely reason that we cannot find any examples of the first generation stars?

A) The first generation stars are too faint to be visible now.

B) The first generation stars formed such a long time ago that the light from them has not yet had time to reach us.

C) The first generation stars were all very massive and exploded as supernova.

D) The first generation stars formed with only H and He and therefore have no spectral features.

E) We do not know how the first generation stars were formed.

C) The first generation stars were all very massive and exploded as supernova.

Why do we think the first generation of stars would be different from stars born today?

A) Without heavy elements, the clouds could not reach as low a temperature as today and had to be more massive to collapse.

B) Without heavy elements, the nuclear reactions at the center of the stars would be very different.

C) Without heavy elements, there was no dust in the clouds and they collapsed faster.

D) The Universe was much denser when the first stars were born.

E) There were no galaxies when the first stars were born.

A) Without heavy elements, the clouds could not reach as low a temperature as today and had to be more massive to collapse.

What is the minimum temperature for a cloud to excite emission lines from H2?

A) 10 K

B) 30 K

C) 100 K

D) 300 K

E) 1000 K

C) 100 K

When is thermal energy trapped in the dense center of a cloud?

A) when the gravity becomes so strong that photons cannot escape

B) when excited molecules collide with other molecules before they can release a photon

C) when the cloud becomes so hot and dense that nuclear fusion begins

D) when magnetic fields trap the radiation

E) when the cloud cools down so much that less light escapes than is produced by contraction

B) when excited molecules collide with other molecules before they can release a photon

What happens to the rotation of a molecular cloud as it collapses to form a star?

A) The rotation rate remains the same and results in stellar rotation.

B) The rotation dissipates and any residual is left in small overall rotation of the star.

C) The rotation rate increases and results in fast rotation of the star.

D) The rotation rate increases and results in a disk of material around a protostar.

E) The rotation increases the speed of collapse and produces more massive stars.

D) The rotation rate increases and results in a disk of material around a protostar.

Which of the following may be caused by a protostellar disk?

A) protostellar jets

B) protostellar winds

C) accretion of material onto the star

D) relatively slow protostellar rotation

E) all of the above

E) all of the above

When does a protostar become a true star?

A) when the star is 1 million years old

B) when the central temperature reaches 1 million Kelvin

C) when nuclear fusion begins in the core

D) when the thermal energy becomes trapped in the center

E) when the stellar winds and jets blow away the surrounding material

C) when nuclear fusion begins in the core

How long does the protostellar stage last for a star like our Sun?

A) 1 million years

B) 3 million years

C) 10 million years

D) 30 million years

E) 100 million years

D) 30 million years

What is the range of timescales for star formation?

A) from 1 million years for the most massive stars up to 10 million years for the least massive stars

B) from 1 million years for the most massive stars up to 100 million years for the least massive stars

C) from 1 million years for the least massive stars up to 10 million years for the most massive stars

D) from 1 million years for the least massive stars up to 100 million years for the most massive stars

E) about 30 million years for all stars, whatever mass

B) from 1 million years for the most massive stars up to 100 million years for the least massive stars

What species absorbs photons in a protostar's outer layers?

A) H

B) H2

C) H+

D) H-

E) dust

D) H-

When does a star become a main-sequence star?

A) when the protostar assembles from a molecular cloud

B) the instant when hydrogen fusion first begins in the star's core

C) when the rate of hydrogen fusion within the star's core is high enough to maintain gravitational equilibrium

D) when a star becomes luminous enough to emit thermal radiation

E) when hydrogen fusion is occurring throughout a star's interior

C) when the rate of hydrogen fusion within the star's core is high enough to maintain gravitational equilibrium

What happens to the surface temperature and luminosity when gravity first assembles a protostar from a collapsing cloud?

A) Its surface temperature and luminosity increase.

B) Its surface temperature remains the same and its luminosity decreases.

C) Its surface temperature and luminosity decrease.

D) Its surface temperature decreases and its luminosity increases.

E) Its surface temperature and luminosity remain the same.

A) Its surface temperature and luminosity increase.

What happens to the surface temperature and luminosity when a protostar undergoes convective contraction?

A) Its surface temperature and luminosity increase.

B) Its surface temperature remains the same and its luminosity decreases.

C) Its surface temperature and luminosity decrease.

D) Its surface temperature decreases and its luminosity increases.

E) Its surface temperature and luminosity remain the same.

B) Its surface temperature remains the same and its luminosity decreases.

What happens to the surface temperature and luminosity when a protostar radiatively contracts?

A) Its surface temperature and luminosity increase.

B) Its surface temperature remains the same and its luminosity decreases.

C) Its surface temperature and luminosity decrease.

D) Its surface temperature decreases and its luminosity increases.

E) Its surface temperature and luminosity remain the same.

A) Its surface temperature and luminosity increase.

When does hydrogen first begin to fuse into helium in the star formation process?

A) when the cloud first begins to contract

B) when the thermal pressure is trapped at the center of the cloud

C) when the protostars undergoes convective contraction

D) when the protostar undergoes radiative contraction

E) only when the star reaches the main-sequence

D) when the protostar undergoes radiative contraction

About how many times more luminous than our Sun is a young solar mass protostar just beginning convective contraction?

A) 2-5

B) 5-10

C) 10-100

D) 100-1000

E) a million

C) 10-100

What is the smallest mass a newborn star can have?

A) 8 times the mass of Jupiter

B) 80 times the mass of Jupiter

C) 800 times the mass of Jupiter

D) about 1/80 the mass of our Sun

E) about 1/800 the mass of our Sun

B) 80 times the mass of Jupiter

What is the difference between brown dwarfs and Jupiter?

A) Brown dwarfs emit infrared radiation.

B) Brown dwarfs are more massive than Jupiter.

C) Brown dwarfs do not orbit main sequence stars.

D) The cores of brown dwarfs are supported by degeneracy pressure.

E) Brown dwarf spectra contain methane absorption lines.

B) Brown dwarfs are more massive than Jupiter.

What are the letters that follow the spectral sequence OBAFGKM?

A) NP

B) YZ

C) LT

D) CD

E) UV

C) LT

What is the greatest mass a newborn star can have

A) 10 solar masses.

B) 20 solar masses.

C) 50 solar masses.

D) 100 solar masses.

E) 200 solar masses.

D) 100 solar masses.

No stars have been found with masses greater than 100 times our Sun because

A) molecular clouds do not have enough material to form such massive stars.

B) they would fragment into binary stars because of their rapid rotation.

C) they would generate so much power that they would blow themselves apart.

D) they shine exclusively at X-ray wavelengths and become difficult to detect.

E) they are not bright enough to be seen nearby.

C) they would generate so much power that they would blow themselves apart.

For every star with a mass greater than 10 solar masses, about how many stars are there with masses less than a solar mass?

A) 1

B) 3

C) 10

D) 30

E) 100

E) 100

Which of the following discoveries, if they existed, would necessitate a reevaluation of our ideas of stellar formation?

A) a cluster of stars that appeared to be 13 billion years old

B) a 100-solar-mass star

C) a 0.01-solar-mass star

D) a molecular cloud without any stars

C) a 0.01-solar-mass star

ASTR 102 Chapter 16- Star Birth - Subjecto.com

ASTR 102 Chapter 16- Star Birth

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Astronomers estimate that new stars form in our galaxy at the rate of about

A) one per year.

B) a few (2-3) per year.

C) ten per year.

D) 20-30 per year.

E) 100 per year.

B) a few (2-3) per year.

By mass, the interstellar medium in our region of the Milky Way consists of

A) 70% Hydrogen, 30% Helium.

B) 70% Hydrogen, 28% Helium, 2% heavier elements.

C) 70% Hydrogen, 20% Helium, 10% heavier elements.

D) 50% Hydrogen, 50% Helium.

E) 50% Hydrogen, 30% Helium, 20% heavier elements.

B) 70% Hydrogen, 28% Helium, 2% heavier elements.

What percentage of a molecular cloud’s mass is interstellar dust?

A) 1%

B) 2%

C) 28%

D) 50%

E) 1-50%, depending on the mass of the molecular cloud

A) 1%

The typical density and temperature of molecular clouds are

A) 100 molecules per cubic centimeter, 10-30 Kelvin.

B) 300 molecules per cubic centimeter, 10-30 Kelvin.

C) 1000 molecules per cubic centimeter, 10-30 Kelvin.

D) 100 molecules per cubic centimeter, 100-300 Kelvin.

E) 300 molecules per cubic centimeter, 100-300 Kelvin.

B) 300 molecules per cubic centimeter, 10-30 Kelvin.

The most abundant molecule in molecular clouds is

A) H2.

B) He2.

C) CO.

D) H2O.

E) HHe.

A) H2.

The typical size of an interstellar dust grain is

A) 1 angstrom.

B) 1 nanometer.

C) 1 micrometer.

D) 1 millimeter.

E) 1 centimeter.

C) 1 micrometer.

What is interstellar reddening?

A) Interstellar dust absorbs more red light than blue light, making stars appear redder than their true color.

B) Interstellar dust absorbs more red light than blue light, making stars appear bluer than their true color.

C) Interstellar dust absorbs more blue light than red light, making stars appear redder than their true color.

D) Interstellar dust absorbs more blue light than red light, making stars appear bluer than their true color.

E) The spectral line shift due to a star’s motion through the interstellar medium.

C) Interstellar dust absorbs more blue light than red light, making stars appear redder than their true color.

If you wanted to observe a molecular cloud, in what wavelength of light would you most likely observe?

A) ultraviolet

B) visible

C) infrared

D) X-ray

E) gamma-ray

C) infrared

What happens to the visible radiation produced by new stars within a molecular cloud?

A) It escapes the cloud completely.

B) It is absorbed by dust grains and heats up the cloud.

C) It is reflected back onto the protostar, heating it up further.

D) The blue light is absorbed and the red light transmitted.

E) It shoots out in bright jets.

B) It is absorbed by dust grains and heats up the cloud.

The thermal pressure of a gas depends on

A) density only.

B) temperature only.

C) density and temperature.

D) composition.

E) gravity.

C) density and temperature.

The gravitational force in a molecular cloud depends on

A) density only.

B) temperature only.

C) density and temperature.

D) composition.

E) thermal pressure.

A) density only.

What prevents the pressure from increasing as a cloud contracts due to its gravity?

A) As the cloud becomes denser, gravity becomes stronger and overcomes the pressure buildup.

B) The pressure is transferred from the center of the cloud to its outer edges where it can dissipate.

C) Thermal energy is converted to radiative energy via molecular collisions and released as photons.

D) Excess pressure is released in jets of material from the young stars.

E) Once the cloud reaches a critical density, the pressure becomes degenerate and independent of temperature.

C) Thermal energy is converted to radiative energy via molecular collisions and released as photons.

Calculations show that gravity begins to overcome thermal pressure in clouds that are

A) less massive than the Sun.

B) more massive than the Sun.

C) more massive than ten times the Sun.

D) more massive than a hundred times the Sun.

E) more massive than a thousand times the Sun.

D) more massive than a hundred times the Sun.

What property of a molecular cloud does not counteract gravitational contraction?

A) thermal pressure

B) turbulent motions

C) magnetic fields

D) fragmentation

D) fragmentation

How do astronomers infer the presence of magnetic fields in molecular clouds?

A) by measuring the amount of interstellar reddening

B) by measuring the Doppler shifts of emission lines from gas clumps in the cloud

C) by measuring the infrared light emitted by the cloud

D) by measuring the polarization of starlight passing through the cloud

E) by measuring the amount by which gravity is reduced

D) by measuring the polarization of starlight passing through the cloud

What is the likely reason that we cannot find any examples of the first generation stars?

A) The first generation stars are too faint to be visible now.

B) The first generation stars formed such a long time ago that the light from them has not yet had time to reach us.

C) The first generation stars were all very massive and exploded as supernova.

D) The first generation stars formed with only H and He and therefore have no spectral features.

E) We do not know how the first generation stars were formed.

C) The first generation stars were all very massive and exploded as supernova.

Why do we think the first generation of stars would be different from stars born today?

A) Without heavy elements, the clouds could not reach as low a temperature as today and had to be more massive to collapse.

B) Without heavy elements, the nuclear reactions at the center of the stars would be very different.

C) Without heavy elements, there was no dust in the clouds and they collapsed faster.

D) The Universe was much denser when the first stars were born.

E) There were no galaxies when the first stars were born.

A) Without heavy elements, the clouds could not reach as low a temperature as today and had to be more massive to collapse.

What is the minimum temperature for a cloud to excite emission lines from H2?

A) 10 K

B) 30 K

C) 100 K

D) 300 K

E) 1000 K

C) 100 K

When is thermal energy trapped in the dense center of a cloud?

A) when the gravity becomes so strong that photons cannot escape

B) when excited molecules collide with other molecules before they can release a photon

C) when the cloud becomes so hot and dense that nuclear fusion begins

D) when magnetic fields trap the radiation

E) when the cloud cools down so much that less light escapes than is produced by contraction

B) when excited molecules collide with other molecules before they can release a photon

What happens to the rotation of a molecular cloud as it collapses to form a star?

A) The rotation rate remains the same and results in stellar rotation.

B) The rotation dissipates and any residual is left in small overall rotation of the star.

C) The rotation rate increases and results in fast rotation of the star.

D) The rotation rate increases and results in a disk of material around a protostar.

E) The rotation increases the speed of collapse and produces more massive stars.

D) The rotation rate increases and results in a disk of material around a protostar.

Which of the following may be caused by a protostellar disk?

A) protostellar jets

B) protostellar winds

C) accretion of material onto the star

D) relatively slow protostellar rotation

E) all of the above

E) all of the above

When does a protostar become a true star?

A) when the star is 1 million years old

B) when the central temperature reaches 1 million Kelvin

C) when nuclear fusion begins in the core

D) when the thermal energy becomes trapped in the center

E) when the stellar winds and jets blow away the surrounding material

C) when nuclear fusion begins in the core

How long does the protostellar stage last for a star like our Sun?

A) 1 million years

B) 3 million years

C) 10 million years

D) 30 million years

E) 100 million years

D) 30 million years

What is the range of timescales for star formation?

A) from 1 million years for the most massive stars up to 10 million years for the least massive stars

B) from 1 million years for the most massive stars up to 100 million years for the least massive stars

C) from 1 million years for the least massive stars up to 10 million years for the most massive stars

D) from 1 million years for the least massive stars up to 100 million years for the most massive stars

E) about 30 million years for all stars, whatever mass

B) from 1 million years for the most massive stars up to 100 million years for the least massive stars

What species absorbs photons in a protostar’s outer layers?

A) H

B) H2

C) H+

D) H-

E) dust

D) H-

When does a star become a main-sequence star?

A) when the protostar assembles from a molecular cloud

B) the instant when hydrogen fusion first begins in the star’s core

C) when the rate of hydrogen fusion within the star’s core is high enough to maintain gravitational equilibrium

D) when a star becomes luminous enough to emit thermal radiation

E) when hydrogen fusion is occurring throughout a star’s interior

C) when the rate of hydrogen fusion within the star’s core is high enough to maintain gravitational equilibrium

What happens to the surface temperature and luminosity when gravity first assembles a protostar from a collapsing cloud?

A) Its surface temperature and luminosity increase.

B) Its surface temperature remains the same and its luminosity decreases.

C) Its surface temperature and luminosity decrease.

D) Its surface temperature decreases and its luminosity increases.

E) Its surface temperature and luminosity remain the same.

A) Its surface temperature and luminosity increase.

What happens to the surface temperature and luminosity when a protostar undergoes convective contraction?

A) Its surface temperature and luminosity increase.

B) Its surface temperature remains the same and its luminosity decreases.

C) Its surface temperature and luminosity decrease.

D) Its surface temperature decreases and its luminosity increases.

E) Its surface temperature and luminosity remain the same.

B) Its surface temperature remains the same and its luminosity decreases.

What happens to the surface temperature and luminosity when a protostar radiatively contracts?

A) Its surface temperature and luminosity increase.

B) Its surface temperature remains the same and its luminosity decreases.

C) Its surface temperature and luminosity decrease.

D) Its surface temperature decreases and its luminosity increases.

E) Its surface temperature and luminosity remain the same.

A) Its surface temperature and luminosity increase.

When does hydrogen first begin to fuse into helium in the star formation process?

A) when the cloud first begins to contract

B) when the thermal pressure is trapped at the center of the cloud

C) when the protostars undergoes convective contraction

D) when the protostar undergoes radiative contraction

E) only when the star reaches the main-sequence

D) when the protostar undergoes radiative contraction

About how many times more luminous than our Sun is a young solar mass protostar just beginning convective contraction?

A) 2-5

B) 5-10

C) 10-100

D) 100-1000

E) a million

C) 10-100

What is the smallest mass a newborn star can have?

A) 8 times the mass of Jupiter

B) 80 times the mass of Jupiter

C) 800 times the mass of Jupiter

D) about 1/80 the mass of our Sun

E) about 1/800 the mass of our Sun

B) 80 times the mass of Jupiter

What is the difference between brown dwarfs and Jupiter?

A) Brown dwarfs emit infrared radiation.

B) Brown dwarfs are more massive than Jupiter.

C) Brown dwarfs do not orbit main sequence stars.

D) The cores of brown dwarfs are supported by degeneracy pressure.

E) Brown dwarf spectra contain methane absorption lines.

B) Brown dwarfs are more massive than Jupiter.

What are the letters that follow the spectral sequence OBAFGKM?

A) NP

B) YZ

C) LT

D) CD

E) UV

C) LT

What is the greatest mass a newborn star can have

A) 10 solar masses.

B) 20 solar masses.

C) 50 solar masses.

D) 100 solar masses.

E) 200 solar masses.

D) 100 solar masses.

No stars have been found with masses greater than 100 times our Sun because

A) molecular clouds do not have enough material to form such massive stars.

B) they would fragment into binary stars because of their rapid rotation.

C) they would generate so much power that they would blow themselves apart.

D) they shine exclusively at X-ray wavelengths and become difficult to detect.

E) they are not bright enough to be seen nearby.

C) they would generate so much power that they would blow themselves apart.

For every star with a mass greater than 10 solar masses, about how many stars are there with masses less than a solar mass?

A) 1

B) 3

C) 10

D) 30

E) 100

E) 100

Which of the following discoveries, if they existed, would necessitate a reevaluation of our ideas of stellar formation?

A) a cluster of stars that appeared to be 13 billion years old

B) a 100-solar-mass star

C) a 0.01-solar-mass star

D) a molecular cloud without any stars

C) a 0.01-solar-mass star

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