started on chap 5 hw, sent in exam1 #1 and #4

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❙Ψ❭ ≐ Ψ(x)
Ψ(x) = ❬x❙Ψ❭
𝓟(x) = │Ψ(x)│²
𝓟(x) = ⎮Ψ(x)⎮²
⌠ ∞
1 = ❬Ψ❙Ψ❭ = ⎮ │Ψ(x)│² dx = 1
⌡-∞
❙Ψ❭ → Ψ(x)
❬Ψ❙ → Ψ⃰(x)
 → A(x)
⌠b
𝓟(a<x<b) = ⎮ │Ψ(x)│² dx
⌡a
│⌠∞ │²
𝓟(Eₙ) = │❬Eₙ❙Ψ❭│² = │⎮ Eₙ⃰(x) Ψ(x) dx │
│⌡-∞ │
x̂ = x
p̂ = ι͟ ∂͟
ħ ∂x
⎛- ħ͟²͟ d͟²͟ + V(x)⎞ φₙ(x) = E φₙ(x)
⎝ 2m dx² ⎠
Boundary conditions:
1) φₙ(x) is continuous.
2) d φₙ(x) is continuous unless V = ∞.
dx
Infinite square potential energy well:
Eₙ = n͟²͟π͟²͟ħ͟², n = 1, 2, 3, ...
2mL²
φₙ(x) = √⎛2͟⎞ sin⎛n͟π͟x͟⎞, n = 1, 2, 3, ...
⎝L⎠ ⎝ L ⎠
Energy eigenstates obey the following properties:
Bra-ket Notation Wavefunction Notation
Normalization
⌠∞
❬Eₙ❙Eₙ❭ = 1 ⎮ │φₙ(x)│² dx = 1
⌡-∞
Orthogonality
⌠∞
❬Eₙ❙Eₘ❭ = δₙₘ ⎮ φₙ⃰(x) φₘ(x) dx = δₙₘ
⌡-∞
Completeness
⌠∞
❬Eₙ❙Eₘ❭ = δₙₘ ⎮ φₙ⃰(x) φₘ(x) dx = δₙₘ
⌡-∞

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A particle in an infinite square well has an initial state vector
❙Ψ(t=0)❭ = A(❙φ₁❭ - ❙φ₂❭ + ι❙φ₃❭).
where ❙φₙ❭ are the energy eigenstates. This also means
❬Ψ(t=0)❙ = A⃰(❬φ₁❙ - ❬φ₂❙ + ι❬φ₃❙)
❙Ψ(t=0)❭ = _͟A͟ (αβ❙φ₁❭ - βγ❙φ₂❭ + αγι❙φ₃❭)
αβγ
In the energy basis,
❙φ₁❭ ≐ ⎛1⎞ ❙φ₂❭ ≐ ⎛0⎞ and ❙φ₃❭ ≐ ⎛0⎞
⎜0⎟ ⎜1⎟ ⎜0⎟
⎝0⎠, ⎝0⎠, ⎝1⎠.
So,
❙Ψ(t=0)❭ ≐ ⎛ A ⎞
⎜-A ⎟
ιA ⎠.
(𝐚) Multiplying the state vector by its magnitude normalizes it.
❙Ψ′(t=0)❭ ≐ __͟A͟__ ⎛ 1 ⎞ = _͟1͟ ⎛ 1 ⎞
√(3A²) ⎜-1 ⎟ √3 ⎜-1 ⎟.
ι ⎠ ⎝ ι

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@ -38,4 +38,4 @@ Performing the multiplication operation on the last two matrices returns the exp
2√2 ⎜ 1 0 1 ⎟ ⎜ 0 0 0 ⎟ = 𝟘.
⎝ 0 1 0 ⎠ ⎝ 1 0 -1 ⎠
It is quite obvious that this operation returns 𝟘 since there are no components that will not match with a 0 throughout the multiplication of these matrices. Therefore, the second expression is also equivalent to the zero matrix 𝟘.
Because each pair of row and column in this matrix has alternating 0s and ±1s, every multiplication operation will return 0. The second expression is therefore equivalent to the zero matrix 𝟘.

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@ -7,13 +7,13 @@ Â ≐ B̂ ≐
B exhibits a degenerate spectrum when it has repeated eigenvalues. The eigenvalues of B are obtained from its characteristic equation.
|⎛ b-λ 0 0 ⎞|
|⎜ 0 -λ -ιb ⎟| = 0, i.e.
|⎝ 0 ιb -λ ⎠|
│⎛ b-λ 0 0 ⎞│
│⎜ 0 -λ -ιb ⎟│ = 𝟘, i.e.
│⎝ 0 ιb -λ ⎠│
(b - λ)(λ² + ι²b²) = (b - λ)(λ² - b²) = (b - λ)(b - λ)(b + λ) = 0.
(a) The eigenvalues for this operator are therefore λ = b,b,-b. Since b appears twice, the operator exhibits a degenerate spectrum.
(𝗮) The eigenvalues for this operator are therefore λ = b,b,-b. Since b appears twice, the operator exhibits a degenerate spectrum.
To find if A and B commute, their commutator need be evaluated. They commute if the value is 0. The commutator of two operators is defined as
@ -28,10 +28,10 @@ For the given operators, then, the commutator is
which reduces to
⎛ ab 0 0 ⎞ ⎛ ab 0 0 ⎞
⎜ 0 0 ιab ⎟ - ⎜ 0 0 ιab ⎟ = 0.
⎜ 0 0 ιab ⎟ - ⎜ 0 0 ιab ⎟ = 𝟘.
⎝ 0 -ιab 0 ⎠ ⎝ 0 -ιab 0 ⎠
(b) Therefore, these operators commute.
(𝗯) Therefore, these operators commute.
Since the operators commute, they share a set of common eigenstates. The eigenstates of  are apparent from inspection:
@ -48,14 +48,28 @@ For B̂, the eigenvalues are already known (λ = b,b,-b.), and using the eigenva
⎜ 0 0 -ιb ⎟ ⎜ β ⎟ = ⎜ -ι b γ ⎟ = b ⎜ β ⎟
⎝ 0 ιb 0 ⎠ ⎝ γ ⎠ ⎝ ι b β ⎠ ⎝ γ
reveals -ι γ = β, which, combined with the normalization condition, will allow the determination of two eigenstates of the B̂. One eigenstate is obvious from inspection,
dicates two possible eigenstates (for the eigenvalue b). One eigenstate is obvious from inspection:
|b₁〉 ≐ ⎛1⎞
⎜0⎟
⎝0⎠.
If β = 1 is chosen, then γ = -ι, and if β = ι, then γ = -1. The two additional eigenstates of B̂ are therefore, after normalizing,
The eigenvalue equation also reveals -ι γ = β. If β = 1 is chosen, then γ = -ι, revealing a second eigenstate, after normalizing:
|b₂〉 ≐ 1 ⎛ 0 ⎞ |b₃〉 ≐ 1 ⎛ 0 ⎞
√2 ⎜ 1 ⎟ √2 ⎜ ι
⎝-ι ⎠ and ⎝ -1 ⎠.
|b₂〉 ≐ 1 ⎛ 0 ⎞
√2 ⎜ 1 ⎟
⎝-ι ⎠.
Similarly, when the eigenvalue -b is used, the eigenvalue equation reveals ι γ = β. So, if β = ι, γ = 1. The third eigenstate is therefore, after normalizing,
|b₃〉 ≐ 1 ⎛0⎞
√2 ⎜ι⎟
⎝1⎠
The complete set of eigenstates of the operator B̂ is
|b₁〉 ≐ ⎛1⎞ |b₂〉 ≐ 1 ⎛ 0 ⎞ |b₃〉 ≐ 1 ⎛0⎞
⎜0⎟ √2 ⎜ 1 ⎟ √2 ⎜ι⎟
⎝0⎠, ⎝-ι ⎠, and ⎝1⎠.
(𝗰) These eigenstates can be expressed as linear combinations of the eigenstates of Â, so they are shared eigenstates between these operators, and so this basis is simultaneously a basis of  and B̂.

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