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Chapter 4 Two-Level Systems
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4.C.1 Two-level systems Let us start with the simplest non-trivial state space, with only two dimensions Despite its simplicity, such space is a good approximation of many physical quantum systems, where all other energy levels could be ignored If the Hamiltonian of the system is H0, then eigenvalue problem can be written as:
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Coupling in a two-level system
To account for either external perturbations or the neglected internal interactions of the two-level system, an additional (small) inter-level coupling term is introduced in the Hamiltonian: In the original (unperturbed) basis the matrix of the perturbed Hamiltonian can be written as: Let us assume that the coupling is time-independent Since the coupling perturbation is observable
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Coupling in a two-level system
What modifications of the two-level system will such coupling introduce? Now, the eigenvalue problem is modified: Thereby one has to find the following relationships: In other words, the new (perturbed) eigen-problem has to be diagonalized
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Coupling in a two-level system
The solution is:
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Coupling in a two-level system
The solution is:
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Coupling in a two-level system
The solution is:
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Coupling in a two-level system
The solution is:
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Evolution of the state vector
Let’s represent the state vector at instant t as a superposition of the two “uncoupled” eigenvectors: Since we get:
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Evolution of the state vector
On the other hand: Recall that if then Thus, assuming
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Evolution of the state vector
On the other hand: Recall that if then Thus, assuming one gets
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Evolution of the state vector
Let us choose a special case: Recall that Then Since
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Evolution of the state vector
The probability amplitude of finding the system at time t in state :
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Evolution of the state vector
The probability amplitude of finding the system at time t in state : Then the probability is The system oscillates between two “unperturbed” states
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Applications: quantum resonance
If then the unperturbed Hamiltonian is 2-fold degenerate The inter-level coupling lifts this degeneracy giving rise to the ground state and an excited state E.g., the benzene molecule It has two equivalent electronic states
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Applications: quantum resonance
However, there is coupling between the two states, so that the perturbed Hamiltonian matrix has non-diagonal elements The two levels become separated This makes the molecule more stable since the ground state energy is below Em while the ground state is a resonant superposition of the unperturbed states
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Applications: quantum resonance
Another example: a singly ionized hydrogen molecule There is coupling between two equivalent electronic states, yielding a lower ground state energy This leads to the delocalization of the electron – the ground state is a resonant superposition of the unperturbed states, which is in essence a chemical bond
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4.A.2 Applications: spin Let us label the elements of the perturbed Hamiltonian matrix as follows:
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Applications: spin The perturbed Hamiltonian matrix
can be rewritten introducing a matrix corresponding to a spin ½ vector operator Then
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Magnetic Moment The vector is called the magnetic dipole
moment of the coil with current Its magnitude is given by μ = IAN The vector always points perpendicular to the plane of the coil The potential energy of the system of a magnetic dipole in a magnetic field depends on the orientation of the dipole in the magnetic field and is equal to:
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Some properties of spin operator
4.B.3 Some properties of spin operator Let’s consider a uniform field B0 and chose the direction of the z axis along the direction of B0 Within the notation So, the eigenvalue problem for H is: The two states correspond to the spin vector parallel and antiparallel to the field
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Some properties of spin operator
4.B.3 Some properties of spin operator We can apply the formulas we derived for the two-level system For example: This is precession
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