The ground state hydrogen atom wave function is solution to which equation.

Question

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Answer 1

Question

Chapter 36, Problem 42P

To determine

The ground state hydrogen atom wave function is solution to which equation.

Expert Solution & Answer

Answer to Problem 42P

The ground state hydrogen atom wave function is solution to Schrodinger’s equation in spherical coordinatesis −ℏ22mr2{∂∂r(r2∂ψ∂r)+[1sinθ∂∂θ(sinθ ∂ψ ∂θ)+1 sin2θ∂2ψ∂ϕ2]}+U(r)ψ=Eψ .

Explanation of Solution

Given:

The ground state hydrogen atom wave functionis ψ100=π−1/2(Z/ a o)3/2e−Zr/ao .

Formula Used:

The expression for Schrodinger’s equation in spherical coordinates is given by,

−ℏ22mr2{∂∂r(r2∂ψ∂r)+[1sinθ∂∂θ(sinθ ∂ψ ∂θ)+1 sin2θ∂2ψ∂ϕ2]}+U(r)ψ=Eψ

The expression U(r) for is given by,

U(r)=−kZe2r

The expression for ao is given by,

ao=ℏ2mke2

Calculation:

The ground state is having spherical symmetry. So,

[1sinθ∂∂θ(sinθ∂ψ∂θ)+1sin2θ∂2ψ∂ϕ2]=0

The value of ∂∂r(r2∂ψ∂r) is calculated as,

∂∂r(r2 ∂ψ ∂r)=∂∂r(r2∂ ∂r( ( Z/ a o ) 3/2 e − Zr/ a o π 1/2 ))=∂∂r(r2( ( Z/ a o ) 3/2 e − Zr/ a o π 1/2 )× −Z a o )= ( Z/ a o ) 3/2 π 1/2 ×−Zao[2re− Zr/ a o +r2e− Zr/ a o ×−Z a o]=re − Zr/ a o π 1/2 ( Z a o )5/2[rZ a o−2]

The Schrodinger’s equation in spherical coordinates is calculated as,

−ℏ22mr2{∂∂r( r 2 ∂ψ ∂r)+[1 sinθ∂ ∂θ( sinθ ∂ψ ∂θ )+1 sin 2 θ ∂ 2 ψ ∂ ϕ 2 ]}+U(r)ψ=Eψ−ℏ22mr2{r e − Zr/ a o π 1/2 ( Z a o )5/2[ rZ a o −2]+0}+(− kZ e 2 r)( e − Zr/ a o π 1/2 ( Z a o ) 3/2 )=Ee − Zr/ a o π 1/2 ( Z a o )3/2−ℏ22mr(Z a o )[rZ a o−2]+(− kZ e 2 r)=E−ℏ22mr(Z ℏ 2 mk e 2 )[rZ ℏ 2 mk e 2 −2]+(− kZ e 2 r)=E

Solve further as,

−ℏ22mr(Z ℏ 2 mk e 2 )[rZ ℏ 2 mk e 2 −2]+(− kZ e 2 r)=EE=−Z2k2e4m2ℏ2

The above expression for E is correct for the ground state energy.

Conclusion:

Therefore, the ground state hydrogen atom wave function ψ100=π−1/2(Z/ a o)3/2e−Zr/ao is a solution to Schrodinger’s equation in spherical coordinates is −ℏ22mr2{∂∂r(r2∂ψ∂r)+[1sinθ∂∂θ(sinθ ∂ψ ∂θ)+1 sin2θ∂2ψ∂ϕ2]}+U(r)ψ=Eψ .

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Answer 2

Question

Chapter 36, Problem 42P

To determine

The ground state hydrogen atom wave function is solution to which equation.

Expert Solution & Answer

Answer to Problem 42P

The ground state hydrogen atom wave function is solution to Schrodinger’s equation in spherical coordinatesis −ℏ22mr2{∂∂r(r2∂ψ∂r)+[1sinθ∂∂θ(sinθ ∂ψ ∂θ)+1 sin2θ∂2ψ∂ϕ2]}+U(r)ψ=Eψ .

Explanation of Solution

Given:

The ground state hydrogen atom wave functionis ψ100=π−1/2(Z/ a o)3/2e−Zr/ao .

Formula Used:

The expression for Schrodinger’s equation in spherical coordinates is given by,

−ℏ22mr2{∂∂r(r2∂ψ∂r)+[1sinθ∂∂θ(sinθ ∂ψ ∂θ)+1 sin2θ∂2ψ∂ϕ2]}+U(r)ψ=Eψ

The expression U(r) for is given by,

U(r)=−kZe2r

The expression for ao is given by,

ao=ℏ2mke2

Calculation:

The ground state is having spherical symmetry. So,

[1sinθ∂∂θ(sinθ∂ψ∂θ)+1sin2θ∂2ψ∂ϕ2]=0

The value of ∂∂r(r2∂ψ∂r) is calculated as,

∂∂r(r2 ∂ψ ∂r)=∂∂r(r2∂ ∂r( ( Z/ a o ) 3/2 e − Zr/ a o π 1/2 ))=∂∂r(r2( ( Z/ a o ) 3/2 e − Zr/ a o π 1/2 )× −Z a o )= ( Z/ a o ) 3/2 π 1/2 ×−Zao[2re− Zr/ a o +r2e− Zr/ a o ×−Z a o]=re − Zr/ a o π 1/2 ( Z a o )5/2[rZ a o−2]

The Schrodinger’s equation in spherical coordinates is calculated as,

−ℏ22mr2{∂∂r( r 2 ∂ψ ∂r)+[1 sinθ∂ ∂θ( sinθ ∂ψ ∂θ )+1 sin 2 θ ∂ 2 ψ ∂ ϕ 2 ]}+U(r)ψ=Eψ−ℏ22mr2{r e − Zr/ a o π 1/2 ( Z a o )5/2[ rZ a o −2]+0}+(− kZ e 2 r)( e − Zr/ a o π 1/2 ( Z a o ) 3/2 )=Ee − Zr/ a o π 1/2 ( Z a o )3/2−ℏ22mr(Z a o )[rZ a o−2]+(− kZ e 2 r)=E−ℏ22mr(Z ℏ 2 mk e 2 )[rZ ℏ 2 mk e 2 −2]+(− kZ e 2 r)=E

Solve further as,

−ℏ22mr(Z ℏ 2 mk e 2 )[rZ ℏ 2 mk e 2 −2]+(− kZ e 2 r)=EE=−Z2k2e4m2ℏ2

The above expression for E is correct for the ground state energy.

Conclusion:

Therefore, the ground state hydrogen atom wave function ψ100=π−1/2(Z/ a o)3/2e−Zr/ao is a solution to Schrodinger’s equation in spherical coordinates is −ℏ22mr2{∂∂r(r2∂ψ∂r)+[1sinθ∂∂θ(sinθ ∂ψ ∂θ)+1 sin2θ∂2ψ∂ϕ2]}+U(r)ψ=Eψ .

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Answer 3

Question

Chapter 36, Problem 42P

To determine

The ground state hydrogen atom wave function is solution to which equation.

Expert Solution & Answer

Answer to Problem 42P

The ground state hydrogen atom wave function is solution to Schrodinger’s equation in spherical coordinatesis −ℏ22mr2{∂∂r(r2∂ψ∂r)+[1sinθ∂∂θ(sinθ ∂ψ ∂θ)+1 sin2θ∂2ψ∂ϕ2]}+U(r)ψ=Eψ .

Explanation of Solution

Given:

The ground state hydrogen atom wave functionis ψ100=π−1/2(Z/ a o)3/2e−Zr/ao .

Formula Used:

The expression for Schrodinger’s equation in spherical coordinates is given by,

−ℏ22mr2{∂∂r(r2∂ψ∂r)+[1sinθ∂∂θ(sinθ ∂ψ ∂θ)+1 sin2θ∂2ψ∂ϕ2]}+U(r)ψ=Eψ

The expression U(r) for is given by,

U(r)=−kZe2r

The expression for ao is given by,

ao=ℏ2mke2

Calculation:

The ground state is having spherical symmetry. So,

[1sinθ∂∂θ(sinθ∂ψ∂θ)+1sin2θ∂2ψ∂ϕ2]=0

The value of ∂∂r(r2∂ψ∂r) is calculated as,

∂∂r(r2 ∂ψ ∂r)=∂∂r(r2∂ ∂r( ( Z/ a o ) 3/2 e − Zr/ a o π 1/2 ))=∂∂r(r2( ( Z/ a o ) 3/2 e − Zr/ a o π 1/2 )× −Z a o )= ( Z/ a o ) 3/2 π 1/2 ×−Zao[2re− Zr/ a o +r2e− Zr/ a o ×−Z a o]=re − Zr/ a o π 1/2 ( Z a o )5/2[rZ a o−2]

The Schrodinger’s equation in spherical coordinates is calculated as,

−ℏ22mr2{∂∂r( r 2 ∂ψ ∂r)+[1 sinθ∂ ∂θ( sinθ ∂ψ ∂θ )+1 sin 2 θ ∂ 2 ψ ∂ ϕ 2 ]}+U(r)ψ=Eψ−ℏ22mr2{r e − Zr/ a o π 1/2 ( Z a o )5/2[ rZ a o −2]+0}+(− kZ e 2 r)( e − Zr/ a o π 1/2 ( Z a o ) 3/2 )=Ee − Zr/ a o π 1/2 ( Z a o )3/2−ℏ22mr(Z a o )[rZ a o−2]+(− kZ e 2 r)=E−ℏ22mr(Z ℏ 2 mk e 2 )[rZ ℏ 2 mk e 2 −2]+(− kZ e 2 r)=E

Solve further as,

−ℏ22mr(Z ℏ 2 mk e 2 )[rZ ℏ 2 mk e 2 −2]+(− kZ e 2 r)=EE=−Z2k2e4m2ℏ2

The above expression for E is correct for the ground state energy.

Conclusion:

Therefore, the ground state hydrogen atom wave function ψ100=π−1/2(Z/ a o)3/2e−Zr/ao is a solution to Schrodinger’s equation in spherical coordinates is −ℏ22mr2{∂∂r(r2∂ψ∂r)+[1sinθ∂∂θ(sinθ ∂ψ ∂θ)+1 sin2θ∂2ψ∂ϕ2]}+U(r)ψ=Eψ .

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Answer 4

Question

Chapter 36, Problem 42P

To determine

The ground state hydrogen atom wave function is solution to which equation.

Expert Solution & Answer

Answer to Problem 42P

The ground state hydrogen atom wave function is solution to Schrodinger’s equation in spherical coordinatesis −ℏ22mr2{∂∂r(r2∂ψ∂r)+[1sinθ∂∂θ(sinθ ∂ψ ∂θ)+1 sin2θ∂2ψ∂ϕ2]}+U(r)ψ=Eψ .

Explanation of Solution

Given:

The ground state hydrogen atom wave functionis ψ100=π−1/2(Z/ a o)3/2e−Zr/ao .

Formula Used:

The expression for Schrodinger’s equation in spherical coordinates is given by,

−ℏ22mr2{∂∂r(r2∂ψ∂r)+[1sinθ∂∂θ(sinθ ∂ψ ∂θ)+1 sin2θ∂2ψ∂ϕ2]}+U(r)ψ=Eψ

The expression U(r) for is given by,

U(r)=−kZe2r

The expression for ao is given by,

ao=ℏ2mke2

Calculation:

The ground state is having spherical symmetry. So,

[1sinθ∂∂θ(sinθ∂ψ∂θ)+1sin2θ∂2ψ∂ϕ2]=0

The value of ∂∂r(r2∂ψ∂r) is calculated as,

∂∂r(r2 ∂ψ ∂r)=∂∂r(r2∂ ∂r( ( Z/ a o ) 3/2 e − Zr/ a o π 1/2 ))=∂∂r(r2( ( Z/ a o ) 3/2 e − Zr/ a o π 1/2 )× −Z a o )= ( Z/ a o ) 3/2 π 1/2 ×−Zao[2re− Zr/ a o +r2e− Zr/ a o ×−Z a o]=re − Zr/ a o π 1/2 ( Z a o )5/2[rZ a o−2]

The Schrodinger’s equation in spherical coordinates is calculated as,

−ℏ22mr2{∂∂r( r 2 ∂ψ ∂r)+[1 sinθ∂ ∂θ( sinθ ∂ψ ∂θ )+1 sin 2 θ ∂ 2 ψ ∂ ϕ 2 ]}+U(r)ψ=Eψ−ℏ22mr2{r e − Zr/ a o π 1/2 ( Z a o )5/2[ rZ a o −2]+0}+(− kZ e 2 r)( e − Zr/ a o π 1/2 ( Z a o ) 3/2 )=Ee − Zr/ a o π 1/2 ( Z a o )3/2−ℏ22mr(Z a o )[rZ a o−2]+(− kZ e 2 r)=E−ℏ22mr(Z ℏ 2 mk e 2 )[rZ ℏ 2 mk e 2 −2]+(− kZ e 2 r)=E

Solve further as,

−ℏ22mr(Z ℏ 2 mk e 2 )[rZ ℏ 2 mk e 2 −2]+(− kZ e 2 r)=EE=−Z2k2e4m2ℏ2

The above expression for E is correct for the ground state energy.

Conclusion:

Therefore, the ground state hydrogen atom wave function ψ100=π−1/2(Z/ a o)3/2e−Zr/ao is a solution to Schrodinger’s equation in spherical coordinates is −ℏ22mr2{∂∂r(r2∂ψ∂r)+[1sinθ∂∂θ(sinθ ∂ψ ∂θ)+1 sin2θ∂2ψ∂ϕ2]}+U(r)ψ=Eψ .

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Answer 5

Chapter 36, Problem 42P

To determine

The ground state hydrogen atom wave function is solution to which equation.

Expert Solution & Answer

Answer to Problem 42P

The ground state hydrogen atom wave function is solution to Schrodinger’s equation in spherical coordinatesis −ℏ22mr2{∂∂r(r2∂ψ∂r)+[1sinθ∂∂θ(sinθ ∂ψ ∂θ)+1 sin2θ∂2ψ∂ϕ2]}+U(r)ψ=Eψ .

Explanation of Solution

Given:

The ground state hydrogen atom wave functionis ψ100=π−1/2(Z/ a o)3/2e−Zr/ao .

Formula Used:

The expression for Schrodinger’s equation in spherical coordinates is given by,

−ℏ22mr2{∂∂r(r2∂ψ∂r)+[1sinθ∂∂θ(sinθ ∂ψ ∂θ)+1 sin2θ∂2ψ∂ϕ2]}+U(r)ψ=Eψ

The expression U(r) for is given by,

U(r)=−kZe2r

The expression for ao is given by,

ao=ℏ2mke2

Calculation:

The ground state is having spherical symmetry. So,

[1sinθ∂∂θ(sinθ∂ψ∂θ)+1sin2θ∂2ψ∂ϕ2]=0

The value of ∂∂r(r2∂ψ∂r) is calculated as,

∂∂r(r2 ∂ψ ∂r)=∂∂r(r2∂ ∂r( ( Z/ a o ) 3/2 e − Zr/ a o π 1/2 ))=∂∂r(r2( ( Z/ a o ) 3/2 e − Zr/ a o π 1/2 )× −Z a o )= ( Z/ a o ) 3/2 π 1/2 ×−Zao[2re− Zr/ a o +r2e− Zr/ a o ×−Z a o]=re − Zr/ a o π 1/2 ( Z a o )5/2[rZ a o−2]

The Schrodinger’s equation in spherical coordinates is calculated as,

−ℏ22mr2{∂∂r( r 2 ∂ψ ∂r)+[1 sinθ∂ ∂θ( sinθ ∂ψ ∂θ )+1 sin 2 θ ∂ 2 ψ ∂ ϕ 2 ]}+U(r)ψ=Eψ−ℏ22mr2{r e − Zr/ a o π 1/2 ( Z a o )5/2[ rZ a o −2]+0}+(− kZ e 2 r)( e − Zr/ a o π 1/2 ( Z a o ) 3/2 )=Ee − Zr/ a o π 1/2 ( Z a o )3/2−ℏ22mr(Z a o )[rZ a o−2]+(− kZ e 2 r)=E−ℏ22mr(Z ℏ 2 mk e 2 )[rZ ℏ 2 mk e 2 −2]+(− kZ e 2 r)=E

Solve further as,

−ℏ22mr(Z ℏ 2 mk e 2 )[rZ ℏ 2 mk e 2 −2]+(− kZ e 2 r)=EE=−Z2k2e4m2ℏ2

The above expression for E is correct for the ground state energy.

Conclusion:

Therefore, the ground state hydrogen atom wave function ψ100=π−1/2(Z/ a o)3/2e−Zr/ao is a solution to Schrodinger’s equation in spherical coordinates is −ℏ22mr2{∂∂r(r2∂ψ∂r)+[1sinθ∂∂θ(sinθ ∂ψ ∂θ)+1 sin2θ∂2ψ∂ϕ2]}+U(r)ψ=Eψ .

Answer 6

Chapter 36, Problem 42P

To determine

The ground state hydrogen atom wave function is solution to which equation.

Expert Solution & Answer

Answer to Problem 42P

The ground state hydrogen atom wave function is solution to Schrodinger’s equation in spherical coordinatesis −ℏ22mr2{∂∂r(r2∂ψ∂r)+[1sinθ∂∂θ(sinθ ∂ψ ∂θ)+1 sin2θ∂2ψ∂ϕ2]}+U(r)ψ=Eψ .

Explanation of Solution

Given:

The ground state hydrogen atom wave functionis ψ100=π−1/2(Z/ a o)3/2e−Zr/ao .

Formula Used:

The expression for Schrodinger’s equation in spherical coordinates is given by,

−ℏ22mr2{∂∂r(r2∂ψ∂r)+[1sinθ∂∂θ(sinθ ∂ψ ∂θ)+1 sin2θ∂2ψ∂ϕ2]}+U(r)ψ=Eψ

The expression U(r) for is given by,

U(r)=−kZe2r

The expression for ao is given by,

ao=ℏ2mke2

Calculation:

The ground state is having spherical symmetry. So,

[1sinθ∂∂θ(sinθ∂ψ∂θ)+1sin2θ∂2ψ∂ϕ2]=0

The value of ∂∂r(r2∂ψ∂r) is calculated as,

∂∂r(r2 ∂ψ ∂r)=∂∂r(r2∂ ∂r( ( Z/ a o ) 3/2 e − Zr/ a o π 1/2 ))=∂∂r(r2( ( Z/ a o ) 3/2 e − Zr/ a o π 1/2 )× −Z a o )= ( Z/ a o ) 3/2 π 1/2 ×−Zao[2re− Zr/ a o +r2e− Zr/ a o ×−Z a o]=re − Zr/ a o π 1/2 ( Z a o )5/2[rZ a o−2]

The Schrodinger’s equation in spherical coordinates is calculated as,

−ℏ22mr2{∂∂r( r 2 ∂ψ ∂r)+[1 sinθ∂ ∂θ( sinθ ∂ψ ∂θ )+1 sin 2 θ ∂ 2 ψ ∂ ϕ 2 ]}+U(r)ψ=Eψ−ℏ22mr2{r e − Zr/ a o π 1/2 ( Z a o )5/2[ rZ a o −2]+0}+(− kZ e 2 r)( e − Zr/ a o π 1/2 ( Z a o ) 3/2 )=Ee − Zr/ a o π 1/2 ( Z a o )3/2−ℏ22mr(Z a o )[rZ a o−2]+(− kZ e 2 r)=E−ℏ22mr(Z ℏ 2 mk e 2 )[rZ ℏ 2 mk e 2 −2]+(− kZ e 2 r)=E

Solve further as,

−ℏ22mr(Z ℏ 2 mk e 2 )[rZ ℏ 2 mk e 2 −2]+(− kZ e 2 r)=EE=−Z2k2e4m2ℏ2

The above expression for E is correct for the ground state energy.

Conclusion:

Therefore, the ground state hydrogen atom wave function ψ100=π−1/2(Z/ a o)3/2e−Zr/ao is a solution to Schrodinger’s equation in spherical coordinates is −ℏ22mr2{∂∂r(r2∂ψ∂r)+[1sinθ∂∂θ(sinθ ∂ψ ∂θ)+1 sin2θ∂2ψ∂ϕ2]}+U(r)ψ=Eψ .

Answer 7

Chapter 36, Problem 42P

To determine

The ground state hydrogen atom wave function is solution to which equation.

Answer 8

Expert Solution & Answer

Answer to Problem 42P

The ground state hydrogen atom wave function is solution to Schrodinger’s equation in spherical coordinatesis −ℏ22mr2{∂∂r(r2∂ψ∂r)+[1sinθ∂∂θ(sinθ ∂ψ ∂θ)+1 sin2θ∂2ψ∂ϕ2]}+U(r)ψ=Eψ .

Answer 9

Expert Solution & Answer

Answer 10

Expert Solution & Answer

Answer 11

Explanation of Solution

Given:

The ground state hydrogen atom wave functionis ψ100=π−1/2(Z/ a o)3/2e−Zr/ao .

Formula Used:

The expression for Schrodinger’s equation in spherical coordinates is given by,

−ℏ22mr2{∂∂r(r2∂ψ∂r)+[1sinθ∂∂θ(sinθ ∂ψ ∂θ)+1 sin2θ∂2ψ∂ϕ2]}+U(r)ψ=Eψ

The expression U(r) for is given by,

U(r)=−kZe2r

The expression for ao is given by,

ao=ℏ2mke2

Calculation:

The ground state is having spherical symmetry. So,

[1sinθ∂∂θ(sinθ∂ψ∂θ)+1sin2θ∂2ψ∂ϕ2]=0

The value of ∂∂r(r2∂ψ∂r) is calculated as,

∂∂r(r2 ∂ψ ∂r)=∂∂r(r2∂ ∂r( ( Z/ a o ) 3/2 e − Zr/ a o π 1/2 ))=∂∂r(r2( ( Z/ a o ) 3/2 e − Zr/ a o π 1/2 )× −Z a o )= ( Z/ a o ) 3/2 π 1/2 ×−Zao[2re− Zr/ a o +r2e− Zr/ a o ×−Z a o]=re − Zr/ a o π 1/2 ( Z a o )5/2[rZ a o−2]

The Schrodinger’s equation in spherical coordinates is calculated as,

−ℏ22mr2{∂∂r( r 2 ∂ψ ∂r)+[1 sinθ∂ ∂θ( sinθ ∂ψ ∂θ )+1 sin 2 θ ∂ 2 ψ ∂ ϕ 2 ]}+U(r)ψ=Eψ−ℏ22mr2{r e − Zr/ a o π 1/2 ( Z a o )5/2[ rZ a o −2]+0}+(− kZ e 2 r)( e − Zr/ a o π 1/2 ( Z a o ) 3/2 )=Ee − Zr/ a o π 1/2 ( Z a o )3/2−ℏ22mr(Z a o )[rZ a o−2]+(− kZ e 2 r)=E−ℏ22mr(Z ℏ 2 mk e 2 )[rZ ℏ 2 mk e 2 −2]+(− kZ e 2 r)=E

Solve further as,

−ℏ22mr(Z ℏ 2 mk e 2 )[rZ ℏ 2 mk e 2 −2]+(− kZ e 2 r)=EE=−Z2k2e4m2ℏ2

The above expression for E is correct for the ground state energy.

Conclusion:

Therefore, the ground state hydrogen atom wave function ψ100=π−1/2(Z/ a o)3/2e−Zr/ao is a solution to Schrodinger’s equation in spherical coordinates is −ℏ22mr2{∂∂r(r2∂ψ∂r)+[1sinθ∂∂θ(sinθ ∂ψ ∂θ)+1 sin2θ∂2ψ∂ϕ2]}+U(r)ψ=Eψ .

Answer 12

Ch. 36 - Prob. 1P Ch. 36 - Prob. 2P Ch. 36 - Prob. 3P Ch. 36 - Prob. 4P Ch. 36 - Prob. 5P Ch. 36 - Prob. 6P Ch. 36 - Prob. 7P Ch. 36 - Prob. 8P Ch. 36 - Prob. 9P Ch. 36 - Prob. 10P

The ground state hydrogen atom wave function is solution to which equation.

The ground state hydrogen atom wave function is solution to which equation.

Answer to Problem 42P

Explanation of Solution

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