Which TWO of the following statements about the universe are true?
- A. The universe is expanding.
- B. The Milky Way galaxy contains most of the stars in the universe.
- C. A star's size, temperature, and composition typically remain constant throughout its life cycle.
- D. A black hole is usually detected by the intense visible light it emits.
Correct Answer & Rationale
Correct Answer: A
Option A accurately reflects current astronomical understanding, as evidence shows the universe is expanding due to the redshift of distant galaxies. Option B is incorrect; while the Milky Way is large, it contains only a small fraction of the universe's stars, which are spread across billions of galaxies. Option C is misleading; stars undergo significant changes in size, temperature, and composition throughout their life cycles, particularly during phases like red giant or supernova. Option D is also false; black holes do not emit visible light; they are detected through their gravitational effects and the radiation from material falling into them.
Option A accurately reflects current astronomical understanding, as evidence shows the universe is expanding due to the redshift of distant galaxies. Option B is incorrect; while the Milky Way is large, it contains only a small fraction of the universe's stars, which are spread across billions of galaxies. Option C is misleading; stars undergo significant changes in size, temperature, and composition throughout their life cycles, particularly during phases like red giant or supernova. Option D is also false; black holes do not emit visible light; they are detected through their gravitational effects and the radiation from material falling into them.
Other Related Questions
An astronaut travels to the Moon, where the magnitude of the force of gravity is one-sixth the magnitude of the force of gravity on Earth. On the Moon, which of the following is true?
- A. The astronaut's mass is one-sixth of his mass on Earth.
- B. The astronaut's weight is one-sixth of his weight on Earth.
- C. The astronaut's mass is six times his mass on Earth.
- D. The astronaut's weight is six times his weight on Earth.
Correct Answer & Rationale
Correct Answer: B
An astronaut's mass remains constant regardless of location; therefore, option A is incorrect as mass on the Moon is the same as on Earth. Option C is also incorrect because mass does not change based on gravitational force. Option D misrepresents weight; weight is dependent on gravity, and since the Moon's gravity is one-sixth that of Earth's, the astronaut's weight is one-sixth, not six times. Thus, option B accurately reflects that the astronaut's weight on the Moon is one-sixth of his weight on Earth, aligning with the relationship between weight and gravitational force.
An astronaut's mass remains constant regardless of location; therefore, option A is incorrect as mass on the Moon is the same as on Earth. Option C is also incorrect because mass does not change based on gravitational force. Option D misrepresents weight; weight is dependent on gravity, and since the Moon's gravity is one-sixth that of Earth's, the astronaut's weight is one-sixth, not six times. Thus, option B accurately reflects that the astronaut's weight on the Moon is one-sixth of his weight on Earth, aligning with the relationship between weight and gravitational force.
Which of the following best describes what happens when two magnets repel each other?
- A. The objects are pulled toward one another.
- B. The objects are pushed away from one another.
- C. An electric spark jumps from one object to another.
- D. Nothing happens until the objects are touched.
Correct Answer & Rationale
Correct Answer: B
When two magnets repel each other, they exert forces that push away from one another due to their like poles (north-north or south-south). This repulsion is a fundamental property of magnetism. Option A is incorrect because it describes attraction, which occurs when opposite poles (north-south) interact. Option C is misleading; electric sparks are not a typical result of magnet repulsion. Option D is also wrong, as repulsion occurs before any physical contact, demonstrating the active interaction between the magnets. Thus, the best description of this phenomenon is that the objects are pushed away from one another.
When two magnets repel each other, they exert forces that push away from one another due to their like poles (north-north or south-south). This repulsion is a fundamental property of magnetism. Option A is incorrect because it describes attraction, which occurs when opposite poles (north-south) interact. Option C is misleading; electric sparks are not a typical result of magnet repulsion. Option D is also wrong, as repulsion occurs before any physical contact, demonstrating the active interaction between the magnets. Thus, the best description of this phenomenon is that the objects are pushed away from one another.
Which of the following best describes a comet?
- A. A small planet orbiting the Sun between Mars and Jupiter.
- B. A chunk composed primarily of metal that enters Earth's atmosphere.
- C. A chunk composed primarily of rock, ice, and dust orbiting the Sun in an elliptical path.
- D. A dark region that appears periodically on the surface of the Sun.
Correct Answer & Rationale
Correct Answer: C
Option C accurately describes a comet as a chunk composed primarily of rock, ice, and dust that orbits the Sun in an elliptical path. This definition captures the essential components and behavior of comets. Option A incorrectly defines a comet as a small planet, which is misleading; comets are distinct from asteroids and do not have the same characteristics. Option B describes a meteoroid, which is a metallic chunk entering Earth's atmosphere, not a comet. Option D refers to sunspots, which are dark regions on the Sun's surface, unrelated to comets. Each incorrect option misrepresents the nature of comets, highlighting the unique characteristics of these celestial bodies.
Option C accurately describes a comet as a chunk composed primarily of rock, ice, and dust that orbits the Sun in an elliptical path. This definition captures the essential components and behavior of comets. Option A incorrectly defines a comet as a small planet, which is misleading; comets are distinct from asteroids and do not have the same characteristics. Option B describes a meteoroid, which is a metallic chunk entering Earth's atmosphere, not a comet. Option D refers to sunspots, which are dark regions on the Sun's surface, unrelated to comets. Each incorrect option misrepresents the nature of comets, highlighting the unique characteristics of these celestial bodies.
The speed of light in empty space, that is, a vacuum, is 300,000 km/s. The speed of sound in empty space is:
- B. greater than 0 but less than 300,000 km/s
- C. 300,000 km/s
- D. greater than 300,000 km/s
Correct Answer & Rationale
Correct Answer: A
The speed of sound requires a medium, such as air or water, to propagate; it cannot travel through a vacuum. Therefore, the speed of sound in empty space is effectively zero. Option B suggests that the speed of sound is greater than 0 but less than 300,000 km/s, which is incorrect because sound cannot exist in a vacuum. Option C states it is 300,000 km/s, which misrepresents sound's nature, as this speed is specific to light. Option D claims it is greater than 300,000 km/s, which is impossible since sound cannot travel in a vacuum at all. Thus, the only valid conclusion is that the speed of sound in empty space is zero.
The speed of sound requires a medium, such as air or water, to propagate; it cannot travel through a vacuum. Therefore, the speed of sound in empty space is effectively zero. Option B suggests that the speed of sound is greater than 0 but less than 300,000 km/s, which is incorrect because sound cannot exist in a vacuum. Option C states it is 300,000 km/s, which misrepresents sound's nature, as this speed is specific to light. Option D claims it is greater than 300,000 km/s, which is impossible since sound cannot travel in a vacuum at all. Thus, the only valid conclusion is that the speed of sound in empty space is zero.