Show that by astute choice of the adjustable parameters Z 1 and Z 2 , the expectation value of the Hamiltonian 〈 H 〉 is less than − 13.6 eV .

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Answer 1

Question

Chapter 8, Problem 8.25P

To determine

Show that by astute choice of the adjustable parameters Z1 and Z2 , the expectation value of the Hamiltonian 〈H〉 is less than −13.6 eV.

Expert Solution & Answer

Answer to Problem 8.25P

It has been prove that by astute choice of the adjustable parameters Z1 and Z2 , the expectation value of the Hamiltonian 〈H〉 is less than −13.6 eV.

Explanation of Solution

The Normalization condition

1=∫|ψ|2d3r1d3r2=|A|2[∫ψ12d3r1∫ψ22d3r2+2∫ψ1ψ2d3r1∫ψ1ψ2d3r2+∫ψ22d3r1∫ψ12d3r2]=|A|2(1+2S2+1)=2|A|2(1+2S2) (I)

Solve for S

S≡∫ψ1(r)ψ2(r)d3r=(Z1Z2)3πa3∫e−(Z1+Z2)r/a(4πr2)dr=4a3(y2)3[2a3(Z1+Z2)3]=(yx)3

Substitute the above equation in equation (I) to find the value of A2

A2=12[1+(yx)6] (II)

Write the Hamiltonian of the given system

H=−ℏ22m(∇12+∇22)−e24πε0(1r1+1r2)+e24πε01|r1−r2|

Then,

Hψ=A{[−ℏ22m(∇12+∇22)−e24πε0(Z1r1+Z2r2)]ψ1(r1)ψ2(r2)+[−ℏ22m(∇12+∇22)−e24πε0(Z1r1+Z2r2)]ψ2(r1)ψ1(r2)} +Ae24πε0{(Z1−1r1+Z2−1r2)ψ1(r1)ψ2(r2)+(Z2−1r1+Z1−1r2)ψ2(r1)ψ1(r2)}+Veeψ (III)

Where, Vee=e24πε01|r1−r2|.

The first term inside the bracket in equation (III) is

={(Z12+Z22)E1ψ1(r1)ψ2(r2)+(Z22+Z12)E1ψ2(r1)ψ1(r2)}={(Z12+Z22)E1ψ}

Thus, equation (III) becomes

Hψ={(Z12+Z22)E1ψ}+Ae24πε0{(Z1−1r1+Z2−1r2)ψ1(r1)ψ2(r2)+(Z2−1r1+Z1−1r2)ψ2(r1)ψ1(r2)}+Veeψ

From the above equation, the expectation value of 〈H〉 is

〈H〉=(Z12+Z22)E1+〈Vee〉+A2e24πε0 ×{〈ψ1(r1)ψ2(r2)+ψ2(r1)ψ1(r2)|((Z1−1r1+Z2−1r2)|ψ1(r1)ψ2(r2)〉+(Z2−1r1+Z1−1r2)|ψ2(r1)ψ1(r2)〉)} (IV)

Solving the terms inside the bracket separately,

{}=(Z1−1)〈ψ1(r1)|1r1|ψ1(r1)〉+(Z2−1)〈ψ2(r2)|1r2|ψ2(r2)〉 +(Z2−1)〈ψ1(r1)|1r1|ψ2(r1)〉〈ψ2(r2)|ψ1(r2)〉 +(Z1−1)〈ψ1(r1)|ψ2(r1)〉〈ψ2(r2)|1r1|ψ1(r2)〉+(Z1−1)〈ψ2(r1)|1r1|ψ1(r1)〉〈ψ1(r2)|ψ2(r2)〉 +(Z2−1)〈ψ2(r1)|ψ1(r1)〉〈ψ1(r2)|1r2|ψ2(r2)〉+(Z2−1)〈ψ2(r1)|1r1|ψ2(r1)〉 +(Z1−1)〈ψ1(r2)|1r2|ψ1(r2)〉=2(Z1−1)〈1r〉1+2(Z2−1)〈1r〉2+2(Z1−1)〈ψ1|ψ2〉〈ψ1|1r1|ψ2〉+2(Z2−1)〈ψ1|ψ2〉〈ψ1|1r1|ψ2〉

But,

〈1r〉1=〈ψ1(r1)|1r1|ψ1(r1)〉=Z1a

〈1r〉2=〈ψ2(r2)|1r2|ψ2(r2)〉=Z2a

Therefore, equation (IV) becomes,

〈H〉=(Z12+Z22)E1+〈Vee〉 +A2e24πε0{1a(Z1−1)Z1+1a(Z2−1)Z2+(Z1+Z2−2)〈ψ1|ψ2〉〈ψ1|1r1|ψ2〉}

Solve the expectation value of Vee

〈Vee〉=e24πε0〈ψ|1|r1−r2||ψ〉=e24πε0A2〈ψ1(r1)ψ2(r2)+ψ2(r1)ψ1(r2)|1|r1−r2||ψ1(r1)ψ2(r2)+ψ2(r1)ψ1(r2)〉=e24πε0A2[2〈ψ1(r1)ψ2(r2)|1|r1−r2||ψ1(r1)ψ2(r2)〉+2〈ψ2(r1)ψ1(r2)|1|r1−r2||ψ2(r1)ψ1(r2)〉]=2e24πε0A2(B+C)

Where, B=〈ψ1(r1)ψ2(r2)|1|r1−r2||ψ1(r1)ψ2(r2)〉 and C=〈ψ2(r1)ψ1(r2)|1|r1−r2||ψ2(r1)ψ1(r2)〉.

Solving for B,

B=Z13Z23(πa3)2∫e−2Z1r1/ae−2Z2r2/a1|r1−r2|d3r1d3r2=Z13Z23(πa3)2πa3Z23(4π)∫0∞e−2Z1r1/a1r1[1−(1+Z2r1a)e−2Z2r1/a]r12dr=4Z13a3∫0∞[r1e−2Z1r1/a−r1e−2(Z1+Z2)r1/a−Z2ar12e−2(Z1+Z2)r1/a]dr1=4Z13a3[(a2Z1)2−(a2(Z1+Z2))2−Z2a2(a2(Z1+Z2))3]

Solving further,

B=Z13a[1Z12−1(Z1+Z2)2−Z2(Z1+Z2)3]=Z1Z2a(Z1+Z2)[1+Z1Z2(Z1+Z2)2]=y24ax[1+y24x2]

Solving for C

C=Z13Z23(πa3)2∫e−Z1r1/ae−Z2r2/ae−Z1r1/ae−Z2r2/a1|r1−r2|d3r1d3r2=Z13Z23(πa3)2πa3Z23(4π)∫0∞e−(Z1+Z2)(r1+r2)/a1|r1−r2|d3r1d3r2=(Z1Z2)3(πa3)25π225645a5(Z1+Z2)5=20a(Z1Z2)3(Z1+Z2)5

Solving further,

C=516ay6x5

Therefore, 〈Vee〉

〈Vee〉=2e24πε0A2(B+C)=2e24πε0A2(y24ax[1+y24x2]+516ay6x5)=2A2(−2E1)y24x(1+y24x2+5y44x4)

The expectation value of the Hamiltonian becomes,

〈H〉=E1{x2−12y2−2[1+(y/x)6][x2−12y2−x+12(x−2)y6x5] −2[1+(y/x)6]y24x(1+y24x2+5y44x4)}

Solving the above equation,

〈H〉=E1(x6+y6)(−x8+2x7+12x6y2−12x5y2−12x5y2−18x3y4+118xy6−12y8)

At x=1.32245, y=1.08505 corresponding to Z1=1.0392, Z2=0.2832.

The expectation value,

〈H〉min=1.0266E1=−13.962 eV

Hence proved.

Conclusion:

It has been prove that by astute choice of the adjustable parameters Z1 and Z2 , the expectation value of the Hamiltonian 〈H〉 is less than −13.6 eV.

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Answer 2

Question

Chapter 8, Problem 8.25P

To determine

Show that by astute choice of the adjustable parameters Z1 and Z2 , the expectation value of the Hamiltonian 〈H〉 is less than −13.6 eV.

Expert Solution & Answer

Answer to Problem 8.25P

It has been prove that by astute choice of the adjustable parameters Z1 and Z2 , the expectation value of the Hamiltonian 〈H〉 is less than −13.6 eV.

Explanation of Solution

The Normalization condition

1=∫|ψ|2d3r1d3r2=|A|2[∫ψ12d3r1∫ψ22d3r2+2∫ψ1ψ2d3r1∫ψ1ψ2d3r2+∫ψ22d3r1∫ψ12d3r2]=|A|2(1+2S2+1)=2|A|2(1+2S2) (I)

Solve for S

S≡∫ψ1(r)ψ2(r)d3r=(Z1Z2)3πa3∫e−(Z1+Z2)r/a(4πr2)dr=4a3(y2)3[2a3(Z1+Z2)3]=(yx)3

Substitute the above equation in equation (I) to find the value of A2

A2=12[1+(yx)6] (II)

Write the Hamiltonian of the given system

H=−ℏ22m(∇12+∇22)−e24πε0(1r1+1r2)+e24πε01|r1−r2|

Then,

Hψ=A{[−ℏ22m(∇12+∇22)−e24πε0(Z1r1+Z2r2)]ψ1(r1)ψ2(r2)+[−ℏ22m(∇12+∇22)−e24πε0(Z1r1+Z2r2)]ψ2(r1)ψ1(r2)} +Ae24πε0{(Z1−1r1+Z2−1r2)ψ1(r1)ψ2(r2)+(Z2−1r1+Z1−1r2)ψ2(r1)ψ1(r2)}+Veeψ (III)

Where, Vee=e24πε01|r1−r2|.

The first term inside the bracket in equation (III) is

={(Z12+Z22)E1ψ1(r1)ψ2(r2)+(Z22+Z12)E1ψ2(r1)ψ1(r2)}={(Z12+Z22)E1ψ}

Thus, equation (III) becomes

Hψ={(Z12+Z22)E1ψ}+Ae24πε0{(Z1−1r1+Z2−1r2)ψ1(r1)ψ2(r2)+(Z2−1r1+Z1−1r2)ψ2(r1)ψ1(r2)}+Veeψ

From the above equation, the expectation value of 〈H〉 is

〈H〉=(Z12+Z22)E1+〈Vee〉+A2e24πε0 ×{〈ψ1(r1)ψ2(r2)+ψ2(r1)ψ1(r2)|((Z1−1r1+Z2−1r2)|ψ1(r1)ψ2(r2)〉+(Z2−1r1+Z1−1r2)|ψ2(r1)ψ1(r2)〉)} (IV)

Solving the terms inside the bracket separately,

{}=(Z1−1)〈ψ1(r1)|1r1|ψ1(r1)〉+(Z2−1)〈ψ2(r2)|1r2|ψ2(r2)〉 +(Z2−1)〈ψ1(r1)|1r1|ψ2(r1)〉〈ψ2(r2)|ψ1(r2)〉 +(Z1−1)〈ψ1(r1)|ψ2(r1)〉〈ψ2(r2)|1r1|ψ1(r2)〉+(Z1−1)〈ψ2(r1)|1r1|ψ1(r1)〉〈ψ1(r2)|ψ2(r2)〉 +(Z2−1)〈ψ2(r1)|ψ1(r1)〉〈ψ1(r2)|1r2|ψ2(r2)〉+(Z2−1)〈ψ2(r1)|1r1|ψ2(r1)〉 +(Z1−1)〈ψ1(r2)|1r2|ψ1(r2)〉=2(Z1−1)〈1r〉1+2(Z2−1)〈1r〉2+2(Z1−1)〈ψ1|ψ2〉〈ψ1|1r1|ψ2〉+2(Z2−1)〈ψ1|ψ2〉〈ψ1|1r1|ψ2〉

But,

〈1r〉1=〈ψ1(r1)|1r1|ψ1(r1)〉=Z1a

〈1r〉2=〈ψ2(r2)|1r2|ψ2(r2)〉=Z2a

Therefore, equation (IV) becomes,

〈H〉=(Z12+Z22)E1+〈Vee〉 +A2e24πε0{1a(Z1−1)Z1+1a(Z2−1)Z2+(Z1+Z2−2)〈ψ1|ψ2〉〈ψ1|1r1|ψ2〉}

Solve the expectation value of Vee

〈Vee〉=e24πε0〈ψ|1|r1−r2||ψ〉=e24πε0A2〈ψ1(r1)ψ2(r2)+ψ2(r1)ψ1(r2)|1|r1−r2||ψ1(r1)ψ2(r2)+ψ2(r1)ψ1(r2)〉=e24πε0A2[2〈ψ1(r1)ψ2(r2)|1|r1−r2||ψ1(r1)ψ2(r2)〉+2〈ψ2(r1)ψ1(r2)|1|r1−r2||ψ2(r1)ψ1(r2)〉]=2e24πε0A2(B+C)

Where, B=〈ψ1(r1)ψ2(r2)|1|r1−r2||ψ1(r1)ψ2(r2)〉 and C=〈ψ2(r1)ψ1(r2)|1|r1−r2||ψ2(r1)ψ1(r2)〉.

Solving for B,

B=Z13Z23(πa3)2∫e−2Z1r1/ae−2Z2r2/a1|r1−r2|d3r1d3r2=Z13Z23(πa3)2πa3Z23(4π)∫0∞e−2Z1r1/a1r1[1−(1+Z2r1a)e−2Z2r1/a]r12dr=4Z13a3∫0∞[r1e−2Z1r1/a−r1e−2(Z1+Z2)r1/a−Z2ar12e−2(Z1+Z2)r1/a]dr1=4Z13a3[(a2Z1)2−(a2(Z1+Z2))2−Z2a2(a2(Z1+Z2))3]

Solving further,

B=Z13a[1Z12−1(Z1+Z2)2−Z2(Z1+Z2)3]=Z1Z2a(Z1+Z2)[1+Z1Z2(Z1+Z2)2]=y24ax[1+y24x2]

Solving for C

C=Z13Z23(πa3)2∫e−Z1r1/ae−Z2r2/ae−Z1r1/ae−Z2r2/a1|r1−r2|d3r1d3r2=Z13Z23(πa3)2πa3Z23(4π)∫0∞e−(Z1+Z2)(r1+r2)/a1|r1−r2|d3r1d3r2=(Z1Z2)3(πa3)25π225645a5(Z1+Z2)5=20a(Z1Z2)3(Z1+Z2)5

Solving further,

C=516ay6x5

Therefore, 〈Vee〉

〈Vee〉=2e24πε0A2(B+C)=2e24πε0A2(y24ax[1+y24x2]+516ay6x5)=2A2(−2E1)y24x(1+y24x2+5y44x4)

The expectation value of the Hamiltonian becomes,

〈H〉=E1{x2−12y2−2[1+(y/x)6][x2−12y2−x+12(x−2)y6x5] −2[1+(y/x)6]y24x(1+y24x2+5y44x4)}

Solving the above equation,

〈H〉=E1(x6+y6)(−x8+2x7+12x6y2−12x5y2−12x5y2−18x3y4+118xy6−12y8)

At x=1.32245, y=1.08505 corresponding to Z1=1.0392, Z2=0.2832.

The expectation value,

〈H〉min=1.0266E1=−13.962 eV

Hence proved.

Conclusion:

It has been prove that by astute choice of the adjustable parameters Z1 and Z2 , the expectation value of the Hamiltonian 〈H〉 is less than −13.6 eV.

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Answer 3

Question

Chapter 8, Problem 8.25P

To determine

Show that by astute choice of the adjustable parameters Z1 and Z2 , the expectation value of the Hamiltonian 〈H〉 is less than −13.6 eV.

Expert Solution & Answer

Answer to Problem 8.25P

It has been prove that by astute choice of the adjustable parameters Z1 and Z2 , the expectation value of the Hamiltonian 〈H〉 is less than −13.6 eV.

Explanation of Solution

The Normalization condition

1=∫|ψ|2d3r1d3r2=|A|2[∫ψ12d3r1∫ψ22d3r2+2∫ψ1ψ2d3r1∫ψ1ψ2d3r2+∫ψ22d3r1∫ψ12d3r2]=|A|2(1+2S2+1)=2|A|2(1+2S2) (I)

Solve for S

S≡∫ψ1(r)ψ2(r)d3r=(Z1Z2)3πa3∫e−(Z1+Z2)r/a(4πr2)dr=4a3(y2)3[2a3(Z1+Z2)3]=(yx)3

Substitute the above equation in equation (I) to find the value of A2

A2=12[1+(yx)6] (II)

Write the Hamiltonian of the given system

H=−ℏ22m(∇12+∇22)−e24πε0(1r1+1r2)+e24πε01|r1−r2|

Then,

Hψ=A{[−ℏ22m(∇12+∇22)−e24πε0(Z1r1+Z2r2)]ψ1(r1)ψ2(r2)+[−ℏ22m(∇12+∇22)−e24πε0(Z1r1+Z2r2)]ψ2(r1)ψ1(r2)} +Ae24πε0{(Z1−1r1+Z2−1r2)ψ1(r1)ψ2(r2)+(Z2−1r1+Z1−1r2)ψ2(r1)ψ1(r2)}+Veeψ (III)

Where, Vee=e24πε01|r1−r2|.

The first term inside the bracket in equation (III) is

={(Z12+Z22)E1ψ1(r1)ψ2(r2)+(Z22+Z12)E1ψ2(r1)ψ1(r2)}={(Z12+Z22)E1ψ}

Thus, equation (III) becomes

Hψ={(Z12+Z22)E1ψ}+Ae24πε0{(Z1−1r1+Z2−1r2)ψ1(r1)ψ2(r2)+(Z2−1r1+Z1−1r2)ψ2(r1)ψ1(r2)}+Veeψ

From the above equation, the expectation value of 〈H〉 is

〈H〉=(Z12+Z22)E1+〈Vee〉+A2e24πε0 ×{〈ψ1(r1)ψ2(r2)+ψ2(r1)ψ1(r2)|((Z1−1r1+Z2−1r2)|ψ1(r1)ψ2(r2)〉+(Z2−1r1+Z1−1r2)|ψ2(r1)ψ1(r2)〉)} (IV)

Solving the terms inside the bracket separately,

{}=(Z1−1)〈ψ1(r1)|1r1|ψ1(r1)〉+(Z2−1)〈ψ2(r2)|1r2|ψ2(r2)〉 +(Z2−1)〈ψ1(r1)|1r1|ψ2(r1)〉〈ψ2(r2)|ψ1(r2)〉 +(Z1−1)〈ψ1(r1)|ψ2(r1)〉〈ψ2(r2)|1r1|ψ1(r2)〉+(Z1−1)〈ψ2(r1)|1r1|ψ1(r1)〉〈ψ1(r2)|ψ2(r2)〉 +(Z2−1)〈ψ2(r1)|ψ1(r1)〉〈ψ1(r2)|1r2|ψ2(r2)〉+(Z2−1)〈ψ2(r1)|1r1|ψ2(r1)〉 +(Z1−1)〈ψ1(r2)|1r2|ψ1(r2)〉=2(Z1−1)〈1r〉1+2(Z2−1)〈1r〉2+2(Z1−1)〈ψ1|ψ2〉〈ψ1|1r1|ψ2〉+2(Z2−1)〈ψ1|ψ2〉〈ψ1|1r1|ψ2〉

But,

〈1r〉1=〈ψ1(r1)|1r1|ψ1(r1)〉=Z1a

〈1r〉2=〈ψ2(r2)|1r2|ψ2(r2)〉=Z2a

Therefore, equation (IV) becomes,

〈H〉=(Z12+Z22)E1+〈Vee〉 +A2e24πε0{1a(Z1−1)Z1+1a(Z2−1)Z2+(Z1+Z2−2)〈ψ1|ψ2〉〈ψ1|1r1|ψ2〉}

Solve the expectation value of Vee

〈Vee〉=e24πε0〈ψ|1|r1−r2||ψ〉=e24πε0A2〈ψ1(r1)ψ2(r2)+ψ2(r1)ψ1(r2)|1|r1−r2||ψ1(r1)ψ2(r2)+ψ2(r1)ψ1(r2)〉=e24πε0A2[2〈ψ1(r1)ψ2(r2)|1|r1−r2||ψ1(r1)ψ2(r2)〉+2〈ψ2(r1)ψ1(r2)|1|r1−r2||ψ2(r1)ψ1(r2)〉]=2e24πε0A2(B+C)

Where, B=〈ψ1(r1)ψ2(r2)|1|r1−r2||ψ1(r1)ψ2(r2)〉 and C=〈ψ2(r1)ψ1(r2)|1|r1−r2||ψ2(r1)ψ1(r2)〉.

Solving for B,

B=Z13Z23(πa3)2∫e−2Z1r1/ae−2Z2r2/a1|r1−r2|d3r1d3r2=Z13Z23(πa3)2πa3Z23(4π)∫0∞e−2Z1r1/a1r1[1−(1+Z2r1a)e−2Z2r1/a]r12dr=4Z13a3∫0∞[r1e−2Z1r1/a−r1e−2(Z1+Z2)r1/a−Z2ar12e−2(Z1+Z2)r1/a]dr1=4Z13a3[(a2Z1)2−(a2(Z1+Z2))2−Z2a2(a2(Z1+Z2))3]

Solving further,

B=Z13a[1Z12−1(Z1+Z2)2−Z2(Z1+Z2)3]=Z1Z2a(Z1+Z2)[1+Z1Z2(Z1+Z2)2]=y24ax[1+y24x2]

Solving for C

C=Z13Z23(πa3)2∫e−Z1r1/ae−Z2r2/ae−Z1r1/ae−Z2r2/a1|r1−r2|d3r1d3r2=Z13Z23(πa3)2πa3Z23(4π)∫0∞e−(Z1+Z2)(r1+r2)/a1|r1−r2|d3r1d3r2=(Z1Z2)3(πa3)25π225645a5(Z1+Z2)5=20a(Z1Z2)3(Z1+Z2)5

Solving further,

C=516ay6x5

Therefore, 〈Vee〉

〈Vee〉=2e24πε0A2(B+C)=2e24πε0A2(y24ax[1+y24x2]+516ay6x5)=2A2(−2E1)y24x(1+y24x2+5y44x4)

The expectation value of the Hamiltonian becomes,

〈H〉=E1{x2−12y2−2[1+(y/x)6][x2−12y2−x+12(x−2)y6x5] −2[1+(y/x)6]y24x(1+y24x2+5y44x4)}

Solving the above equation,

〈H〉=E1(x6+y6)(−x8+2x7+12x6y2−12x5y2−12x5y2−18x3y4+118xy6−12y8)

At x=1.32245, y=1.08505 corresponding to Z1=1.0392, Z2=0.2832.

The expectation value,

〈H〉min=1.0266E1=−13.962 eV

Hence proved.

Conclusion:

It has been prove that by astute choice of the adjustable parameters Z1 and Z2 , the expectation value of the Hamiltonian 〈H〉 is less than −13.6 eV.

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Answer 4

Question

Chapter 8, Problem 8.25P

To determine

Show that by astute choice of the adjustable parameters Z1 and Z2 , the expectation value of the Hamiltonian 〈H〉 is less than −13.6 eV.

Expert Solution & Answer

Answer to Problem 8.25P

It has been prove that by astute choice of the adjustable parameters Z1 and Z2 , the expectation value of the Hamiltonian 〈H〉 is less than −13.6 eV.

Explanation of Solution

The Normalization condition

1=∫|ψ|2d3r1d3r2=|A|2[∫ψ12d3r1∫ψ22d3r2+2∫ψ1ψ2d3r1∫ψ1ψ2d3r2+∫ψ22d3r1∫ψ12d3r2]=|A|2(1+2S2+1)=2|A|2(1+2S2) (I)

Solve for S

S≡∫ψ1(r)ψ2(r)d3r=(Z1Z2)3πa3∫e−(Z1+Z2)r/a(4πr2)dr=4a3(y2)3[2a3(Z1+Z2)3]=(yx)3

Substitute the above equation in equation (I) to find the value of A2

A2=12[1+(yx)6] (II)

Write the Hamiltonian of the given system

H=−ℏ22m(∇12+∇22)−e24πε0(1r1+1r2)+e24πε01|r1−r2|

Then,

Hψ=A{[−ℏ22m(∇12+∇22)−e24πε0(Z1r1+Z2r2)]ψ1(r1)ψ2(r2)+[−ℏ22m(∇12+∇22)−e24πε0(Z1r1+Z2r2)]ψ2(r1)ψ1(r2)} +Ae24πε0{(Z1−1r1+Z2−1r2)ψ1(r1)ψ2(r2)+(Z2−1r1+Z1−1r2)ψ2(r1)ψ1(r2)}+Veeψ (III)

Where, Vee=e24πε01|r1−r2|.

The first term inside the bracket in equation (III) is

={(Z12+Z22)E1ψ1(r1)ψ2(r2)+(Z22+Z12)E1ψ2(r1)ψ1(r2)}={(Z12+Z22)E1ψ}

Thus, equation (III) becomes

Hψ={(Z12+Z22)E1ψ}+Ae24πε0{(Z1−1r1+Z2−1r2)ψ1(r1)ψ2(r2)+(Z2−1r1+Z1−1r2)ψ2(r1)ψ1(r2)}+Veeψ

From the above equation, the expectation value of 〈H〉 is

〈H〉=(Z12+Z22)E1+〈Vee〉+A2e24πε0 ×{〈ψ1(r1)ψ2(r2)+ψ2(r1)ψ1(r2)|((Z1−1r1+Z2−1r2)|ψ1(r1)ψ2(r2)〉+(Z2−1r1+Z1−1r2)|ψ2(r1)ψ1(r2)〉)} (IV)

Solving the terms inside the bracket separately,

{}=(Z1−1)〈ψ1(r1)|1r1|ψ1(r1)〉+(Z2−1)〈ψ2(r2)|1r2|ψ2(r2)〉 +(Z2−1)〈ψ1(r1)|1r1|ψ2(r1)〉〈ψ2(r2)|ψ1(r2)〉 +(Z1−1)〈ψ1(r1)|ψ2(r1)〉〈ψ2(r2)|1r1|ψ1(r2)〉+(Z1−1)〈ψ2(r1)|1r1|ψ1(r1)〉〈ψ1(r2)|ψ2(r2)〉 +(Z2−1)〈ψ2(r1)|ψ1(r1)〉〈ψ1(r2)|1r2|ψ2(r2)〉+(Z2−1)〈ψ2(r1)|1r1|ψ2(r1)〉 +(Z1−1)〈ψ1(r2)|1r2|ψ1(r2)〉=2(Z1−1)〈1r〉1+2(Z2−1)〈1r〉2+2(Z1−1)〈ψ1|ψ2〉〈ψ1|1r1|ψ2〉+2(Z2−1)〈ψ1|ψ2〉〈ψ1|1r1|ψ2〉

But,

〈1r〉1=〈ψ1(r1)|1r1|ψ1(r1)〉=Z1a

〈1r〉2=〈ψ2(r2)|1r2|ψ2(r2)〉=Z2a

Therefore, equation (IV) becomes,

〈H〉=(Z12+Z22)E1+〈Vee〉 +A2e24πε0{1a(Z1−1)Z1+1a(Z2−1)Z2+(Z1+Z2−2)〈ψ1|ψ2〉〈ψ1|1r1|ψ2〉}

Solve the expectation value of Vee

〈Vee〉=e24πε0〈ψ|1|r1−r2||ψ〉=e24πε0A2〈ψ1(r1)ψ2(r2)+ψ2(r1)ψ1(r2)|1|r1−r2||ψ1(r1)ψ2(r2)+ψ2(r1)ψ1(r2)〉=e24πε0A2[2〈ψ1(r1)ψ2(r2)|1|r1−r2||ψ1(r1)ψ2(r2)〉+2〈ψ2(r1)ψ1(r2)|1|r1−r2||ψ2(r1)ψ1(r2)〉]=2e24πε0A2(B+C)

Where, B=〈ψ1(r1)ψ2(r2)|1|r1−r2||ψ1(r1)ψ2(r2)〉 and C=〈ψ2(r1)ψ1(r2)|1|r1−r2||ψ2(r1)ψ1(r2)〉.

Solving for B,

B=Z13Z23(πa3)2∫e−2Z1r1/ae−2Z2r2/a1|r1−r2|d3r1d3r2=Z13Z23(πa3)2πa3Z23(4π)∫0∞e−2Z1r1/a1r1[1−(1+Z2r1a)e−2Z2r1/a]r12dr=4Z13a3∫0∞[r1e−2Z1r1/a−r1e−2(Z1+Z2)r1/a−Z2ar12e−2(Z1+Z2)r1/a]dr1=4Z13a3[(a2Z1)2−(a2(Z1+Z2))2−Z2a2(a2(Z1+Z2))3]

Solving further,

B=Z13a[1Z12−1(Z1+Z2)2−Z2(Z1+Z2)3]=Z1Z2a(Z1+Z2)[1+Z1Z2(Z1+Z2)2]=y24ax[1+y24x2]

Solving for C

C=Z13Z23(πa3)2∫e−Z1r1/ae−Z2r2/ae−Z1r1/ae−Z2r2/a1|r1−r2|d3r1d3r2=Z13Z23(πa3)2πa3Z23(4π)∫0∞e−(Z1+Z2)(r1+r2)/a1|r1−r2|d3r1d3r2=(Z1Z2)3(πa3)25π225645a5(Z1+Z2)5=20a(Z1Z2)3(Z1+Z2)5

Solving further,

C=516ay6x5

Therefore, 〈Vee〉

〈Vee〉=2e24πε0A2(B+C)=2e24πε0A2(y24ax[1+y24x2]+516ay6x5)=2A2(−2E1)y24x(1+y24x2+5y44x4)

The expectation value of the Hamiltonian becomes,

〈H〉=E1{x2−12y2−2[1+(y/x)6][x2−12y2−x+12(x−2)y6x5] −2[1+(y/x)6]y24x(1+y24x2+5y44x4)}

Solving the above equation,

〈H〉=E1(x6+y6)(−x8+2x7+12x6y2−12x5y2−12x5y2−18x3y4+118xy6−12y8)

At x=1.32245, y=1.08505 corresponding to Z1=1.0392, Z2=0.2832.

The expectation value,

〈H〉min=1.0266E1=−13.962 eV

Hence proved.

Conclusion:

It has been prove that by astute choice of the adjustable parameters Z1 and Z2 , the expectation value of the Hamiltonian 〈H〉 is less than −13.6 eV.

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Answer 5

Chapter 8, Problem 8.25P

To determine

Show that by astute choice of the adjustable parameters Z1 and Z2 , the expectation value of the Hamiltonian 〈H〉 is less than −13.6 eV.

Expert Solution & Answer

Answer to Problem 8.25P

It has been prove that by astute choice of the adjustable parameters Z1 and Z2 , the expectation value of the Hamiltonian 〈H〉 is less than −13.6 eV.

Explanation of Solution

The Normalization condition

1=∫|ψ|2d3r1d3r2=|A|2[∫ψ12d3r1∫ψ22d3r2+2∫ψ1ψ2d3r1∫ψ1ψ2d3r2+∫ψ22d3r1∫ψ12d3r2]=|A|2(1+2S2+1)=2|A|2(1+2S2) (I)

Solve for S

S≡∫ψ1(r)ψ2(r)d3r=(Z1Z2)3πa3∫e−(Z1+Z2)r/a(4πr2)dr=4a3(y2)3[2a3(Z1+Z2)3]=(yx)3

Substitute the above equation in equation (I) to find the value of A2

A2=12[1+(yx)6] (II)

Write the Hamiltonian of the given system

H=−ℏ22m(∇12+∇22)−e24πε0(1r1+1r2)+e24πε01|r1−r2|

Then,

Hψ=A{[−ℏ22m(∇12+∇22)−e24πε0(Z1r1+Z2r2)]ψ1(r1)ψ2(r2)+[−ℏ22m(∇12+∇22)−e24πε0(Z1r1+Z2r2)]ψ2(r1)ψ1(r2)} +Ae24πε0{(Z1−1r1+Z2−1r2)ψ1(r1)ψ2(r2)+(Z2−1r1+Z1−1r2)ψ2(r1)ψ1(r2)}+Veeψ (III)

Where, Vee=e24πε01|r1−r2|.

The first term inside the bracket in equation (III) is

={(Z12+Z22)E1ψ1(r1)ψ2(r2)+(Z22+Z12)E1ψ2(r1)ψ1(r2)}={(Z12+Z22)E1ψ}

Thus, equation (III) becomes

Hψ={(Z12+Z22)E1ψ}+Ae24πε0{(Z1−1r1+Z2−1r2)ψ1(r1)ψ2(r2)+(Z2−1r1+Z1−1r2)ψ2(r1)ψ1(r2)}+Veeψ

From the above equation, the expectation value of 〈H〉 is

〈H〉=(Z12+Z22)E1+〈Vee〉+A2e24πε0 ×{〈ψ1(r1)ψ2(r2)+ψ2(r1)ψ1(r2)|((Z1−1r1+Z2−1r2)|ψ1(r1)ψ2(r2)〉+(Z2−1r1+Z1−1r2)|ψ2(r1)ψ1(r2)〉)} (IV)

Solving the terms inside the bracket separately,

{}=(Z1−1)〈ψ1(r1)|1r1|ψ1(r1)〉+(Z2−1)〈ψ2(r2)|1r2|ψ2(r2)〉 +(Z2−1)〈ψ1(r1)|1r1|ψ2(r1)〉〈ψ2(r2)|ψ1(r2)〉 +(Z1−1)〈ψ1(r1)|ψ2(r1)〉〈ψ2(r2)|1r1|ψ1(r2)〉+(Z1−1)〈ψ2(r1)|1r1|ψ1(r1)〉〈ψ1(r2)|ψ2(r2)〉 +(Z2−1)〈ψ2(r1)|ψ1(r1)〉〈ψ1(r2)|1r2|ψ2(r2)〉+(Z2−1)〈ψ2(r1)|1r1|ψ2(r1)〉 +(Z1−1)〈ψ1(r2)|1r2|ψ1(r2)〉=2(Z1−1)〈1r〉1+2(Z2−1)〈1r〉2+2(Z1−1)〈ψ1|ψ2〉〈ψ1|1r1|ψ2〉+2(Z2−1)〈ψ1|ψ2〉〈ψ1|1r1|ψ2〉

But,

〈1r〉1=〈ψ1(r1)|1r1|ψ1(r1)〉=Z1a

〈1r〉2=〈ψ2(r2)|1r2|ψ2(r2)〉=Z2a

Therefore, equation (IV) becomes,

〈H〉=(Z12+Z22)E1+〈Vee〉 +A2e24πε0{1a(Z1−1)Z1+1a(Z2−1)Z2+(Z1+Z2−2)〈ψ1|ψ2〉〈ψ1|1r1|ψ2〉}

Solve the expectation value of Vee

〈Vee〉=e24πε0〈ψ|1|r1−r2||ψ〉=e24πε0A2〈ψ1(r1)ψ2(r2)+ψ2(r1)ψ1(r2)|1|r1−r2||ψ1(r1)ψ2(r2)+ψ2(r1)ψ1(r2)〉=e24πε0A2[2〈ψ1(r1)ψ2(r2)|1|r1−r2||ψ1(r1)ψ2(r2)〉+2〈ψ2(r1)ψ1(r2)|1|r1−r2||ψ2(r1)ψ1(r2)〉]=2e24πε0A2(B+C)

Where, B=〈ψ1(r1)ψ2(r2)|1|r1−r2||ψ1(r1)ψ2(r2)〉 and C=〈ψ2(r1)ψ1(r2)|1|r1−r2||ψ2(r1)ψ1(r2)〉.

Solving for B,

B=Z13Z23(πa3)2∫e−2Z1r1/ae−2Z2r2/a1|r1−r2|d3r1d3r2=Z13Z23(πa3)2πa3Z23(4π)∫0∞e−2Z1r1/a1r1[1−(1+Z2r1a)e−2Z2r1/a]r12dr=4Z13a3∫0∞[r1e−2Z1r1/a−r1e−2(Z1+Z2)r1/a−Z2ar12e−2(Z1+Z2)r1/a]dr1=4Z13a3[(a2Z1)2−(a2(Z1+Z2))2−Z2a2(a2(Z1+Z2))3]

Solving further,

B=Z13a[1Z12−1(Z1+Z2)2−Z2(Z1+Z2)3]=Z1Z2a(Z1+Z2)[1+Z1Z2(Z1+Z2)2]=y24ax[1+y24x2]

Solving for C

C=Z13Z23(πa3)2∫e−Z1r1/ae−Z2r2/ae−Z1r1/ae−Z2r2/a1|r1−r2|d3r1d3r2=Z13Z23(πa3)2πa3Z23(4π)∫0∞e−(Z1+Z2)(r1+r2)/a1|r1−r2|d3r1d3r2=(Z1Z2)3(πa3)25π225645a5(Z1+Z2)5=20a(Z1Z2)3(Z1+Z2)5

Solving further,

C=516ay6x5

Therefore, 〈Vee〉

〈Vee〉=2e24πε0A2(B+C)=2e24πε0A2(y24ax[1+y24x2]+516ay6x5)=2A2(−2E1)y24x(1+y24x2+5y44x4)

The expectation value of the Hamiltonian becomes,

〈H〉=E1{x2−12y2−2[1+(y/x)6][x2−12y2−x+12(x−2)y6x5] −2[1+(y/x)6]y24x(1+y24x2+5y44x4)}

Solving the above equation,

〈H〉=E1(x6+y6)(−x8+2x7+12x6y2−12x5y2−12x5y2−18x3y4+118xy6−12y8)

At x=1.32245, y=1.08505 corresponding to Z1=1.0392, Z2=0.2832.

The expectation value,

〈H〉min=1.0266E1=−13.962 eV

Hence proved.

Conclusion:

It has been prove that by astute choice of the adjustable parameters Z1 and Z2 , the expectation value of the Hamiltonian 〈H〉 is less than −13.6 eV.

Answer 6

Chapter 8, Problem 8.25P

To determine

Show that by astute choice of the adjustable parameters Z1 and Z2 , the expectation value of the Hamiltonian 〈H〉 is less than −13.6 eV.

Expert Solution & Answer

Answer to Problem 8.25P

It has been prove that by astute choice of the adjustable parameters Z1 and Z2 , the expectation value of the Hamiltonian 〈H〉 is less than −13.6 eV.

Explanation of Solution

The Normalization condition

1=∫|ψ|2d3r1d3r2=|A|2[∫ψ12d3r1∫ψ22d3r2+2∫ψ1ψ2d3r1∫ψ1ψ2d3r2+∫ψ22d3r1∫ψ12d3r2]=|A|2(1+2S2+1)=2|A|2(1+2S2) (I)

Solve for S

S≡∫ψ1(r)ψ2(r)d3r=(Z1Z2)3πa3∫e−(Z1+Z2)r/a(4πr2)dr=4a3(y2)3[2a3(Z1+Z2)3]=(yx)3

Substitute the above equation in equation (I) to find the value of A2

A2=12[1+(yx)6] (II)

Write the Hamiltonian of the given system

H=−ℏ22m(∇12+∇22)−e24πε0(1r1+1r2)+e24πε01|r1−r2|

Then,

Hψ=A{[−ℏ22m(∇12+∇22)−e24πε0(Z1r1+Z2r2)]ψ1(r1)ψ2(r2)+[−ℏ22m(∇12+∇22)−e24πε0(Z1r1+Z2r2)]ψ2(r1)ψ1(r2)} +Ae24πε0{(Z1−1r1+Z2−1r2)ψ1(r1)ψ2(r2)+(Z2−1r1+Z1−1r2)ψ2(r1)ψ1(r2)}+Veeψ (III)

Where, Vee=e24πε01|r1−r2|.

The first term inside the bracket in equation (III) is

={(Z12+Z22)E1ψ1(r1)ψ2(r2)+(Z22+Z12)E1ψ2(r1)ψ1(r2)}={(Z12+Z22)E1ψ}

Thus, equation (III) becomes

Hψ={(Z12+Z22)E1ψ}+Ae24πε0{(Z1−1r1+Z2−1r2)ψ1(r1)ψ2(r2)+(Z2−1r1+Z1−1r2)ψ2(r1)ψ1(r2)}+Veeψ

From the above equation, the expectation value of 〈H〉 is

〈H〉=(Z12+Z22)E1+〈Vee〉+A2e24πε0 ×{〈ψ1(r1)ψ2(r2)+ψ2(r1)ψ1(r2)|((Z1−1r1+Z2−1r2)|ψ1(r1)ψ2(r2)〉+(Z2−1r1+Z1−1r2)|ψ2(r1)ψ1(r2)〉)} (IV)

Solving the terms inside the bracket separately,

{}=(Z1−1)〈ψ1(r1)|1r1|ψ1(r1)〉+(Z2−1)〈ψ2(r2)|1r2|ψ2(r2)〉 +(Z2−1)〈ψ1(r1)|1r1|ψ2(r1)〉〈ψ2(r2)|ψ1(r2)〉 +(Z1−1)〈ψ1(r1)|ψ2(r1)〉〈ψ2(r2)|1r1|ψ1(r2)〉+(Z1−1)〈ψ2(r1)|1r1|ψ1(r1)〉〈ψ1(r2)|ψ2(r2)〉 +(Z2−1)〈ψ2(r1)|ψ1(r1)〉〈ψ1(r2)|1r2|ψ2(r2)〉+(Z2−1)〈ψ2(r1)|1r1|ψ2(r1)〉 +(Z1−1)〈ψ1(r2)|1r2|ψ1(r2)〉=2(Z1−1)〈1r〉1+2(Z2−1)〈1r〉2+2(Z1−1)〈ψ1|ψ2〉〈ψ1|1r1|ψ2〉+2(Z2−1)〈ψ1|ψ2〉〈ψ1|1r1|ψ2〉

But,

〈1r〉1=〈ψ1(r1)|1r1|ψ1(r1)〉=Z1a

〈1r〉2=〈ψ2(r2)|1r2|ψ2(r2)〉=Z2a

Therefore, equation (IV) becomes,

〈H〉=(Z12+Z22)E1+〈Vee〉 +A2e24πε0{1a(Z1−1)Z1+1a(Z2−1)Z2+(Z1+Z2−2)〈ψ1|ψ2〉〈ψ1|1r1|ψ2〉}

Solve the expectation value of Vee

〈Vee〉=e24πε0〈ψ|1|r1−r2||ψ〉=e24πε0A2〈ψ1(r1)ψ2(r2)+ψ2(r1)ψ1(r2)|1|r1−r2||ψ1(r1)ψ2(r2)+ψ2(r1)ψ1(r2)〉=e24πε0A2[2〈ψ1(r1)ψ2(r2)|1|r1−r2||ψ1(r1)ψ2(r2)〉+2〈ψ2(r1)ψ1(r2)|1|r1−r2||ψ2(r1)ψ1(r2)〉]=2e24πε0A2(B+C)

Where, B=〈ψ1(r1)ψ2(r2)|1|r1−r2||ψ1(r1)ψ2(r2)〉 and C=〈ψ2(r1)ψ1(r2)|1|r1−r2||ψ2(r1)ψ1(r2)〉.

Solving for B,

B=Z13Z23(πa3)2∫e−2Z1r1/ae−2Z2r2/a1|r1−r2|d3r1d3r2=Z13Z23(πa3)2πa3Z23(4π)∫0∞e−2Z1r1/a1r1[1−(1+Z2r1a)e−2Z2r1/a]r12dr=4Z13a3∫0∞[r1e−2Z1r1/a−r1e−2(Z1+Z2)r1/a−Z2ar12e−2(Z1+Z2)r1/a]dr1=4Z13a3[(a2Z1)2−(a2(Z1+Z2))2−Z2a2(a2(Z1+Z2))3]

Solving further,

B=Z13a[1Z12−1(Z1+Z2)2−Z2(Z1+Z2)3]=Z1Z2a(Z1+Z2)[1+Z1Z2(Z1+Z2)2]=y24ax[1+y24x2]

Solving for C

C=Z13Z23(πa3)2∫e−Z1r1/ae−Z2r2/ae−Z1r1/ae−Z2r2/a1|r1−r2|d3r1d3r2=Z13Z23(πa3)2πa3Z23(4π)∫0∞e−(Z1+Z2)(r1+r2)/a1|r1−r2|d3r1d3r2=(Z1Z2)3(πa3)25π225645a5(Z1+Z2)5=20a(Z1Z2)3(Z1+Z2)5

Solving further,

C=516ay6x5

Therefore, 〈Vee〉

〈Vee〉=2e24πε0A2(B+C)=2e24πε0A2(y24ax[1+y24x2]+516ay6x5)=2A2(−2E1)y24x(1+y24x2+5y44x4)

The expectation value of the Hamiltonian becomes,

〈H〉=E1{x2−12y2−2[1+(y/x)6][x2−12y2−x+12(x−2)y6x5] −2[1+(y/x)6]y24x(1+y24x2+5y44x4)}

Solving the above equation,

〈H〉=E1(x6+y6)(−x8+2x7+12x6y2−12x5y2−12x5y2−18x3y4+118xy6−12y8)

At x=1.32245, y=1.08505 corresponding to Z1=1.0392, Z2=0.2832.

The expectation value,

〈H〉min=1.0266E1=−13.962 eV

Hence proved.

Conclusion:

It has been prove that by astute choice of the adjustable parameters Z1 and Z2 , the expectation value of the Hamiltonian 〈H〉 is less than −13.6 eV.

Answer 7

Chapter 8, Problem 8.25P

To determine

Show that by astute choice of the adjustable parameters Z1 and Z2 , the expectation value of the Hamiltonian 〈H〉 is less than −13.6 eV.

Answer 8

Expert Solution & Answer

Answer to Problem 8.25P

It has been prove that by astute choice of the adjustable parameters Z1 and Z2 , the expectation value of the Hamiltonian 〈H〉 is less than −13.6 eV.

Answer 9

Expert Solution & Answer

Answer 10

Expert Solution & Answer

Answer 11

Explanation of Solution

The Normalization condition

1=∫|ψ|2d3r1d3r2=|A|2[∫ψ12d3r1∫ψ22d3r2+2∫ψ1ψ2d3r1∫ψ1ψ2d3r2+∫ψ22d3r1∫ψ12d3r2]=|A|2(1+2S2+1)=2|A|2(1+2S2) (I)

Solve for S

S≡∫ψ1(r)ψ2(r)d3r=(Z1Z2)3πa3∫e−(Z1+Z2)r/a(4πr2)dr=4a3(y2)3[2a3(Z1+Z2)3]=(yx)3

Substitute the above equation in equation (I) to find the value of A2

A2=12[1+(yx)6] (II)

Write the Hamiltonian of the given system

H=−ℏ22m(∇12+∇22)−e24πε0(1r1+1r2)+e24πε01|r1−r2|

Then,

Hψ=A{[−ℏ22m(∇12+∇22)−e24πε0(Z1r1+Z2r2)]ψ1(r1)ψ2(r2)+[−ℏ22m(∇12+∇22)−e24πε0(Z1r1+Z2r2)]ψ2(r1)ψ1(r2)} +Ae24πε0{(Z1−1r1+Z2−1r2)ψ1(r1)ψ2(r2)+(Z2−1r1+Z1−1r2)ψ2(r1)ψ1(r2)}+Veeψ (III)

Where, Vee=e24πε01|r1−r2|.

The first term inside the bracket in equation (III) is

={(Z12+Z22)E1ψ1(r1)ψ2(r2)+(Z22+Z12)E1ψ2(r1)ψ1(r2)}={(Z12+Z22)E1ψ}

Thus, equation (III) becomes

Hψ={(Z12+Z22)E1ψ}+Ae24πε0{(Z1−1r1+Z2−1r2)ψ1(r1)ψ2(r2)+(Z2−1r1+Z1−1r2)ψ2(r1)ψ1(r2)}+Veeψ

From the above equation, the expectation value of 〈H〉 is

〈H〉=(Z12+Z22)E1+〈Vee〉+A2e24πε0 ×{〈ψ1(r1)ψ2(r2)+ψ2(r1)ψ1(r2)|((Z1−1r1+Z2−1r2)|ψ1(r1)ψ2(r2)〉+(Z2−1r1+Z1−1r2)|ψ2(r1)ψ1(r2)〉)} (IV)

Solving the terms inside the bracket separately,

{}=(Z1−1)〈ψ1(r1)|1r1|ψ1(r1)〉+(Z2−1)〈ψ2(r2)|1r2|ψ2(r2)〉 +(Z2−1)〈ψ1(r1)|1r1|ψ2(r1)〉〈ψ2(r2)|ψ1(r2)〉 +(Z1−1)〈ψ1(r1)|ψ2(r1)〉〈ψ2(r2)|1r1|ψ1(r2)〉+(Z1−1)〈ψ2(r1)|1r1|ψ1(r1)〉〈ψ1(r2)|ψ2(r2)〉 +(Z2−1)〈ψ2(r1)|ψ1(r1)〉〈ψ1(r2)|1r2|ψ2(r2)〉+(Z2−1)〈ψ2(r1)|1r1|ψ2(r1)〉 +(Z1−1)〈ψ1(r2)|1r2|ψ1(r2)〉=2(Z1−1)〈1r〉1+2(Z2−1)〈1r〉2+2(Z1−1)〈ψ1|ψ2〉〈ψ1|1r1|ψ2〉+2(Z2−1)〈ψ1|ψ2〉〈ψ1|1r1|ψ2〉

But,

〈1r〉1=〈ψ1(r1)|1r1|ψ1(r1)〉=Z1a

〈1r〉2=〈ψ2(r2)|1r2|ψ2(r2)〉=Z2a

Therefore, equation (IV) becomes,

〈H〉=(Z12+Z22)E1+〈Vee〉 +A2e24πε0{1a(Z1−1)Z1+1a(Z2−1)Z2+(Z1+Z2−2)〈ψ1|ψ2〉〈ψ1|1r1|ψ2〉}

Solve the expectation value of Vee

〈Vee〉=e24πε0〈ψ|1|r1−r2||ψ〉=e24πε0A2〈ψ1(r1)ψ2(r2)+ψ2(r1)ψ1(r2)|1|r1−r2||ψ1(r1)ψ2(r2)+ψ2(r1)ψ1(r2)〉=e24πε0A2[2〈ψ1(r1)ψ2(r2)|1|r1−r2||ψ1(r1)ψ2(r2)〉+2〈ψ2(r1)ψ1(r2)|1|r1−r2||ψ2(r1)ψ1(r2)〉]=2e24πε0A2(B+C)

Where, B=〈ψ1(r1)ψ2(r2)|1|r1−r2||ψ1(r1)ψ2(r2)〉 and C=〈ψ2(r1)ψ1(r2)|1|r1−r2||ψ2(r1)ψ1(r2)〉.

Solving for B,

B=Z13Z23(πa3)2∫e−2Z1r1/ae−2Z2r2/a1|r1−r2|d3r1d3r2=Z13Z23(πa3)2πa3Z23(4π)∫0∞e−2Z1r1/a1r1[1−(1+Z2r1a)e−2Z2r1/a]r12dr=4Z13a3∫0∞[r1e−2Z1r1/a−r1e−2(Z1+Z2)r1/a−Z2ar12e−2(Z1+Z2)r1/a]dr1=4Z13a3[(a2Z1)2−(a2(Z1+Z2))2−Z2a2(a2(Z1+Z2))3]

Solving further,

B=Z13a[1Z12−1(Z1+Z2)2−Z2(Z1+Z2)3]=Z1Z2a(Z1+Z2)[1+Z1Z2(Z1+Z2)2]=y24ax[1+y24x2]

Solving for C

C=Z13Z23(πa3)2∫e−Z1r1/ae−Z2r2/ae−Z1r1/ae−Z2r2/a1|r1−r2|d3r1d3r2=Z13Z23(πa3)2πa3Z23(4π)∫0∞e−(Z1+Z2)(r1+r2)/a1|r1−r2|d3r1d3r2=(Z1Z2)3(πa3)25π225645a5(Z1+Z2)5=20a(Z1Z2)3(Z1+Z2)5

Solving further,

C=516ay6x5

Therefore, 〈Vee〉

〈Vee〉=2e24πε0A2(B+C)=2e24πε0A2(y24ax[1+y24x2]+516ay6x5)=2A2(−2E1)y24x(1+y24x2+5y44x4)

The expectation value of the Hamiltonian becomes,

〈H〉=E1{x2−12y2−2[1+(y/x)6][x2−12y2−x+12(x−2)y6x5] −2[1+(y/x)6]y24x(1+y24x2+5y44x4)}

Solving the above equation,

〈H〉=E1(x6+y6)(−x8+2x7+12x6y2−12x5y2−12x5y2−18x3y4+118xy6−12y8)

At x=1.32245, y=1.08505 corresponding to Z1=1.0392, Z2=0.2832.

The expectation value,

〈H〉min=1.0266E1=−13.962 eV

Hence proved.

Conclusion:

It has been prove that by astute choice of the adjustable parameters Z1 and Z2 , the expectation value of the Hamiltonian 〈H〉 is less than −13.6 eV.

Answer 12

Ch. 8.1 - Prob. 8.1P Ch. 8.1 - Prob. 8.2P Ch. 8.1 - Prob. 8.3P Ch. 8.1 - Prob. 8.4P Ch. 8.1 - Prob. 8.5P Ch. 8.1 - Prob. 8.6P Ch. 8.2 - Prob. 8.7P Ch. 8.2 - Prob. 8.8P Ch. 8.3 - Prob. 8.9P Ch. 8.3 - Prob. 8.10P

Show that by astute choice of the adjustable parameters Z 1 and Z 2 , the expectation value of the Hamiltonian 〈 H 〉 is less than − 13.6 eV .

Show that by astute choice of the adjustable parameters Z1 and Z2 , the expectation value of the Hamiltonian 〈H〉 is less than −13.6 eV.

Answer to Problem 8.25P

Explanation of Solution

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