Fossilized remains of prehistoric organisms are typically found in which of the following types of rock?
- A. Metamorphic rock
- B. Igneous rock
- C. Sedimentary rock
- D. Molten rock
Correct Answer & Rationale
Correct Answer: C
Fossilized remains are most commonly found in sedimentary rock, which forms from the accumulation of sediment and organic material in layers. This environment allows for the preservation of organisms. Metamorphic rock (A) forms under high pressure and temperature, altering existing rocks and typically destroying fossils. Igneous rock (B) is created from cooled magma or lava, which does not preserve organic material. Molten rock (D) refers to rock in a liquid state, which cannot contain fossils as it is not solidified. Thus, sedimentary rock is the ideal environment for fossil preservation.
Fossilized remains are most commonly found in sedimentary rock, which forms from the accumulation of sediment and organic material in layers. This environment allows for the preservation of organisms. Metamorphic rock (A) forms under high pressure and temperature, altering existing rocks and typically destroying fossils. Igneous rock (B) is created from cooled magma or lava, which does not preserve organic material. Molten rock (D) refers to rock in a liquid state, which cannot contain fossils as it is not solidified. Thus, sedimentary rock is the ideal environment for fossil preservation.
Other Related Questions
An object is lifted above the floor to a height X, as illustrated, and then released. Which of the following best describes the object's energy?
- A. At height X, the energy is kinetic and changes to potential as the object falls.
- B. At height X, the energy is potential and changes to kinetic as the object falls.
- C. At height X, the energy is zero and the object gains both kinetic and potential energy as it falls.
- D. At height X, the energy is potential and the object gains kinetic energy as it falls, while its potential energy decreases.
Correct Answer & Rationale
Correct Answer: B
At height X, the object possesses gravitational potential energy due to its elevated position. As it falls, this potential energy is converted into kinetic energy, which increases as the object accelerates toward the ground. Option A is incorrect because at height X, the energy is primarily potential, not kinetic. Option C misrepresents the energy state; the energy is not zero at height X. Option D partially describes the process but does not clarify that the potential energy is transformed into kinetic energy, which is essential to understanding energy conservation during the fall.
At height X, the object possesses gravitational potential energy due to its elevated position. As it falls, this potential energy is converted into kinetic energy, which increases as the object accelerates toward the ground. Option A is incorrect because at height X, the energy is primarily potential, not kinetic. Option C misrepresents the energy state; the energy is not zero at height X. Option D partially describes the process but does not clarify that the potential energy is transformed into kinetic energy, which is essential to understanding energy conservation during the fall.
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.
Which of the following best explains why an ice skater is able to coast on ice for a long distance without pushing off in a straight line across the ice?
- A. The force of friction on the blades of the skates is greater than the force of friction on the ice.
- B. The force of friction on the blades of the skates is less than the force of friction on the ice.
- C. The ice exerts a constant forward force on the skater.
- D. The buoyant force on the blades of the skates is greater than the weight of the skater.
Correct Answer & Rationale
Correct Answer: B
An ice skater can glide smoothly due to the minimal friction between the skate blades and the ice, which is significantly lower than the friction experienced on other surfaces. This reduced friction allows the skater to maintain momentum over longer distances without needing to push off. Option A is incorrect because it suggests greater friction on the blades, which would hinder movement. Option C is misleading, as the ice does not exert a forward force; instead, the skater continues moving due to existing momentum. Option D is also wrong; while buoyancy affects weight in water, it does not apply to ice skating, where weight and friction are the primary factors.
An ice skater can glide smoothly due to the minimal friction between the skate blades and the ice, which is significantly lower than the friction experienced on other surfaces. This reduced friction allows the skater to maintain momentum over longer distances without needing to push off. Option A is incorrect because it suggests greater friction on the blades, which would hinder movement. Option C is misleading, as the ice does not exert a forward force; instead, the skater continues moving due to existing momentum. Option D is also wrong; while buoyancy affects weight in water, it does not apply to ice skating, where weight and friction are the primary factors.
Which of the following plant structures are specialized for the absorption of water and nutrients from the environment?
- A. Roots
- B. Leaves
- C. Flowers
- D. Stems
Correct Answer & Rationale
Correct Answer: A
Roots are specialized structures designed for the absorption of water and nutrients from the soil, featuring a large surface area and root hairs that enhance their efficiency. Leaves primarily function in photosynthesis and gas exchange, not nutrient absorption. Flowers are reproductive structures that facilitate pollination and seed production, playing no direct role in nutrient uptake. Stems support the plant and transport water and nutrients between roots and leaves, but they do not absorb them. Thus, roots are uniquely equipped for this essential task.
Roots are specialized structures designed for the absorption of water and nutrients from the soil, featuring a large surface area and root hairs that enhance their efficiency. Leaves primarily function in photosynthesis and gas exchange, not nutrient absorption. Flowers are reproductive structures that facilitate pollination and seed production, playing no direct role in nutrient uptake. Stems support the plant and transport water and nutrients between roots and leaves, but they do not absorb them. Thus, roots are uniquely equipped for this essential task.