Learning Path
Question & Answer1
Understand Question2
Review Options3
Learn Explanation4
Explore TopicChoose the Best Answer
A
A → B → C → D
B
B → A → D → C
C
C → A → B → D
D
B → C → A → D
Understanding the Answer
Let's break down why this is correct
Answer
The correct sequence starts with measuring the particle’s position (A). Once we have that position, we apply the Heisenberg Uncertainty Principle (B) to see how this measurement limits how precisely we can know the particle’s momentum. With that limitation in mind, we determine the momentum (C) knowing it will be uncertain within the bounds set by the principle. Finally, we calculate expectation values (D) to describe the average behavior of the system. For example, if we pin a particle to a narrow spot, the principle tells us its momentum must spread out, and we use that spread to compute average kinetic energy.
Detailed Explanation
First you measure where a particle is. Other options are incorrect because It puts the uncertainty rule before the position measurement, which is impossible because the rule only applies after you have a position value; It starts by finding momentum before measuring position, which skips the essential step of knowing where the particle is.
Key Concepts
Heisenberg Uncertainty Principle
Expectation Values
Measurement in Quantum Mechanics
Topic
Energy and Uncertainty in Quantum Mechanics
Difficulty
hard level question
Cognitive Level
understand
Practice Similar Questions
Test your understanding with related questions
1
Question 1In quantum mechanics, the uncertainty principle indicates that the more accurately we know a particle's position, the less accurately we can know its momentum. Which of the following statements best describes this relationship in terms of probabilities?
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Question 2In quantum mechanics, how does the concept of operators relate to the uncertainty principle, specifically in measuring the energy of a particle?
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3
Question 3In the context of quantum mechanics, how does the complementarity principle relate to the uncertainty in measuring both the energy and the position of entangled particles?
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Question 4Which of the following statements accurately reflect the implications of the Heisenberg Uncertainty Principle in quantum mechanics? (Select all that apply)
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5
Question 5Energy in quantum mechanics is to uncertainty as position in classical mechanics is to what?
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6
Question 6Arrange the following concepts in the correct logical sequence that describes the interactions of energy and uncertainty in quantum mechanics: A) Measurement of position, B) Application of the Heisenberg Uncertainty Principle, C) Determination of momentum, D) Calculation of expectation values.
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Question 7In quantum mechanics, the uncertainty principle indicates that the more accurately we know a particle's position, the less accurately we can know its momentum. Which of the following statements best describes this relationship in terms of probabilities?
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8
Question 8In quantum mechanics, how does the concept of operators relate to the uncertainty principle, specifically in measuring the energy of a particle?
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Question 9In the context of quantum mechanics, how does the complementarity principle relate to the uncertainty in measuring both the energy and the position of entangled particles?
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Question 10Which of the following statements accurately reflect the implications of the Heisenberg Uncertainty Principle in quantum mechanics? (Select all that apply)
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