In the context of quantum information and the properties of Bell states, when the 1st qubit of a Bell state is measured in a certain basis and the 2nd qubit is measured in a basis that is rotated by a specific angle theta, the probability of obtaining projection to the corresponding vector is indeed equal to the square of the sine of theta. To understand this phenomenon comprehensively, we need to delve into the principles of quantum mechanics, specifically the concept of quantum entanglement and measurements in different bases.
Bell states are a set of four maximally entangled quantum states that play a crucial role in quantum information processing. One of the most famous Bell states is the maximally entangled state known as the singlet state, also denoted as |Φ⁻⟩. This state is characterized by the property that the two qubits are maximally entangled, meaning that the state of one qubit is intrinsically linked to the state of the other qubit, regardless of the physical distance between them.
When we perform measurements on the qubits of a Bell state in different bases, we introduce the concept of basis rotations. In quantum mechanics, the choice of basis affects the outcome of measurements and can lead to different probabilities of obtaining specific measurement results. The act of rotating the basis by an angle theta introduces a phase shift that influences the probabilities of measurement outcomes.
To analyze the scenario where the 1st qubit is measured in a certain basis and the 2nd qubit is measured in a basis rotated by an angle theta, we need to consider the effect of this rotation on the measurement outcomes. The probability of obtaining projection to the corresponding vector is determined by the relationship between the angle theta and the sine of theta.
In quantum mechanics, the probability amplitudes of measurement outcomes are related to the inner product of the state being measured and the basis states. The square of the sine of the angle theta arises in this context due to the interference effects that occur when measuring entangled states in rotated bases. The interference patterns are a consequence of the superposition principle in quantum mechanics, where different measurement paths can interfere constructively or destructively, leading to varying probabilities of measurement outcomes.
For example, let's consider the singlet Bell state |Φ⁻⟩ = (|01⟩ – |10⟩) / √2. If we measure the 1st qubit in the computational basis {|0⟩, |1⟩} and then rotate the basis for the 2nd qubit by an angle theta, the probability of obtaining projection to the corresponding vector will indeed be given by the square of the sine of theta.
This result highlights the intricate relationship between basis rotations, quantum entanglement, and measurement probabilities in quantum information processing. By understanding how basis rotations impact measurement outcomes in entangled states like Bell states, researchers can manipulate quantum systems to perform various quantum information tasks efficiently and accurately.
The probability of obtaining projection to the corresponding vector when measuring the 1st qubit of a Bell state in a certain basis and the 2nd qubit in a basis rotated by an angle theta is equal to the square of the sine of theta, showcasing the fascinating interplay between quantum mechanics principles and quantum information properties.
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