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Answer :
The value is:
(a) The energy eigenvalues of the two-particle system are given by E = 2w(l₁(l₁+1) + l₂(l₂+1) - l₃(l₃+1)), where l₁, l₂, and l₃ are the quantum numbers associated with the angular momentum of each particle.
(b) For the specific case of l₁ = 1, l₂ = 2, m₁ = 0, and m₂ = 1, the possible energy eigenvalues are E = 12w, E = 8w, and E = 4w, corresponding to l₃ = 1, l₃ = 2, and l₃ = 3, respectively.
To find the energy eigenvalues and corresponding eigenstates, we need to solve the Schrödinger equation for the given Hamiltonian.
(a) Energy Eigenvalues and Eigenstates:
The Hamiltonian for the two-particle system is given by:
H = w(L₁² + L₂²) + (L₁ . L₂) ħ + (w/ħ) L₁ . L₂
To find the energy eigenvalues and eigenstates, we need to solve the Schrödinger equation:
H |ψ⟩ = E |ψ⟩
Let's assume that the eigenstate can be expressed as a product of individual angular momentum eigenstates:
|ψ⟩ = |l₁, m₁⟩ ⊗ |l₂, m₂⟩
where |l₁, m₁⟩ represents the eigenstate of the angular momentum of particle 1 and |l₂, m₂⟩ represents the eigenstate of the angular momentum of particle 2.
Substituting the eigenstate into the Schrödinger equation, we get:
H |l₁, m₁⟩ ⊗ |l₂, m₂⟩ = E |l₁, m₁⟩ ⊗ |l₂, m₂⟩
Expanding the Hamiltonian, we have:
H = w(L₁² + L₂²) + (L₁ . L₂) ħ + (w/ħ) L₁ . L₂
To simplify the expression, we can use the commutation relation between angular momentum operators:
[L₁, L₂] = iħ L₃
where L₃ is the angular momentum operator along the z-axis.
Using this relation, we can rewrite the Hamiltonian as:
H = w(L₁² + L₂²) + (L₁ . L₂) ħ + (w/ħ) L₁ . L₂
= w(L₁² + L₂²) + (L₁ . L₂) ħ + (w/ħ) (1/2)(L₁² + L₂² - L₃² - ħ²)
Substituting the eigenstates into the Schrödinger equation and applying the Hamiltonian, we get:
E |l₁, m₁⟩ ⊗ |l₂, m₂⟩ = w(l₁(l₁+1) + l₂(l₂+1) + (l₁(l₁+1) + l₂(l₂+1) - l₃(l₃+1) - 1/4) + w(l₁(l₁+1) + l₂(l₂+1) - l₃(l₃+1) - 1/4)) ħ² |l₁, m₁⟩ ⊗ |l₂, m₂⟩
Simplifying the equation, we obtain:
E = 2w(l₁(l₁+1) + l₂(l₂+1) - l₃(l₃+1))
The energy eigenvalues depend on the quantum numbers l₁, l₂, and l₃.
(b) Given l₁ = 1, l₂ = 2, m₁ = 0, and m₂ = 1, we can find the energy eigenvalues using the expression derived in part (a):
E = 2w(l₁(l₁+1) + l₂(l₂+1) - l₃(l₃+1))
Substituting the values, we have:
E = 2w(1(1+1) + 2(2+1) - l₃(l₃+1))
To find the possible energy eigenvalues, we need to consider all possible values of l₃. The allowed values for l₃ are given by the triangular inequality:
|l₁ - l₂| ≤ l₃ ≤ l₁ + l₂
In this case, |1 - 2| ≤ l₃ ≤ 1 + 2, which gives 1 ≤ l₃ ≤ 3.
Therefore, the possible energy eigenvalues for this system are obtained by substituting different values of l₃:
For l₃ = 1:
E = 2w(1(1+1) + 2(2+1) - 1(1+1))
= 2w(6) = 12w
For l₃ = 2:
E = 2w(1(1+1) + 2(2+1) - 2(2+1))
= 2w(4) = 8w
For l₃ = 3:
E = 2w(1(1+1) + 2(2+1) - 3(3+1))
= 2w(2) = 4w
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