Learning Path
Question & Answer1
Understand Question2
Review Options3
Learn Explanation4
Explore TopicChoose the Best Answer
A
Operators can precisely measure energy without any uncertainty.
B
The uncertainty relation states that the measurement of energy is independent of time.
C
Operators represent observables, and due to their non-commutative nature, they lead to uncertainty in measurements.
D
Operators only apply to position measurements and not to energy.
Understanding the Answer
Let's break down why this is correct
Answer
In quantum mechanics, an operator is a mathematical tool that tells us how to measure a physical quantity, like energy. The energy operator (Hamiltonian) does not commute with the time operator, meaning that measuring energy precisely changes our knowledge of the particle’s time, and vice versa. This non‑commutation leads directly to the uncertainty principle: the more accurately we know a particle’s energy, the less precisely we can know the time at which that energy was measured. For example, if a particle’s energy is pinned down to a very narrow value, the wave packet’s phase evolves slowly, making the exact instant of measurement fuzzy. Thus, operators and their commutation relations explain why we cannot simultaneously know a particle’s exact energy and the exact time of that measurement.
Detailed Explanation
Operators are tools that give the value of a physical quantity, like energy. Other options are incorrect because The belief that operators can give an exact energy value ignores the fact that quantum measurements are probabilistic; The idea that energy measurement is independent of time is a misunderstanding of the energy‑time uncertainty relation.
Key Concepts
operators in quantum mechanics
applications of quantum mechanics
Topic
Energy and Uncertainty in Quantum Mechanics
Difficulty
medium 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?
easyComputer-science
Practice
2
Question 2In quantum mechanics, how does the concept of operators relate to the uncertainty principle, specifically in measuring the energy of a particle?
mediumComputer-science
Practice
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?
hardComputer-science
Practice
4
Question 4Which of the following statements accurately reflect the implications of the Heisenberg Uncertainty Principle in quantum mechanics? (Select all that apply)
mediumComputer-science
Practice
5
Question 5Energy in quantum mechanics is to uncertainty as position in classical mechanics is to what?
easyComputer-science
Practice
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.
hardComputer-science
Practice
7
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?
easyComputer-science
Practice
8
Question 8In 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?
hardComputer-science
Practice
9
Question 9Energy in quantum mechanics is to uncertainty as position in classical mechanics is to what?
easyComputer-science
Practice
10
Question 10Arrange 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.
hardComputer-science
Practice
Ready to Master More Topics?
Join thousands of students using Seekh's interactive learning platform to excel in their studies with personalized practice and detailed explanations.