College Physics
College Physics
11th Edition
ISBN: 9781305952300
Author: Raymond A. Serway, Chris Vuille
Publisher: Cengage Learning
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Chapter 28, Problem 19P

(a)

To determine

The energy of the longest wavelength.

(a)

Expert Solution
Check Mark

Answer to Problem 19P

The energy of the longest wavelength is 1.889eV .

Explanation of Solution

Formula to calculate the energy of the photon of the longest wavelength is,

Ephoton=E3E2

  • E2andE3 are the energy of the second and third level
  • Ephoton is energy of the photon,

Substitute (1.512eV) for E3 , (3.401eV) for E2 to find Ephoton .

Ephoton=(1.512eV)(3.401eV)=1.889eV

Thus, the energy of the photon of the longest wavelength is 1.889eV .

Conclusion:

Therefore, the energy of the photon of the longest wavelength is 1.889eV .

(b)

To determine

The wavelength of the photon of the longest wavelength.

(b)

Expert Solution
Check Mark

Answer to Problem 19P

The wavelength of the longest wavelength is 6.58×107m .

Explanation of Solution

Formula to calculate the wavelength of the photon of the longest wavelength is,

λ=hcEphoton

  • h is the Planck’s constant
  • c is the speed of light
  • Ephoton is energy of the photon,

From unit conversion,

1eV=1.6×1019J

Substitute 6.63×1034J-s for h , 3×108m/s for c , 1.889eV for Ephoton to find λ .

λ=(6.63×1034J-s)(3×108m/s)(1.889eV)(1eV1.6×1019J)=6.58×107m

Thus, the wavelength of the photon of the longest wavelength is 6.58×107m .

Conclusion:

Therefore, the wavelength of the photon of the longest wavelength is 6.58×107m .

(c)

To determine

The energy of the shortest photon wavelength.

(c)

Expert Solution
Check Mark

Answer to Problem 19P

The energy of the shortest photon wavelength is 3.02eV .

Explanation of Solution

Formula to calculate the energy of the photon of the shortest wavelength is,

Ephoton=E6E2

  • E2andE6 are the energy of the second and sixth level
  • Ephoton is energy of the photon,

Substitute (0.378eV) for E6 , (3.401eV) for E2 to find Ephoton .

Ephoton=(0.378eV)(3.401eV)=3.02eV

Thus, the energy of the photon of the shortest wavelength is 3.02eV .

Conclusion:

Therefore, the energy of the photon of the shortest wavelength is 3.02eV .

(d)

To determine

The wavelength of the photon of the shortest wavelength.

(d)

Expert Solution
Check Mark

Answer to Problem 19P

The wavelength of the shortest wavelength is 4.12×107m .

Explanation of Solution

Formula to calculate the wavelength of the photon of the shortest wavelength is,

λ=hcEphoton

  • h is the Planck’s constant
  • c is the speed of light
  • Ephoton is energy of the photon,

From unit conversion,

1eV=1.6×1019J

Substitute 6.63×1034J-s for h , 3×108m/s for c , 3.02eV for Ephoton to find λ .

λ=(6.63×1034J-s)(3×108m/s)(3.02eV)(1eV1.6×1019J)=4.12×107m

Thus, the wavelength of the photon of the shortest wavelength is 4.12×107m .

Conclusion:

Therefore, the wavelength of the photon of the shortest wavelength is 4.12×107m .

(e)

To determine

The shortest possible wavelength in the Balmar series.

(e)

Expert Solution
Check Mark

Answer to Problem 19P

The shortest possible wavelength in the Balmar series is 3.66×107m .

Explanation of Solution

Section1:

To determine: The energy of the shortest possible wavelength.

Answer: The energy of the shortest possible wavelength. is 3.401eV .

Explanation:

Formula to calculate the energy of the photon of the shortest wavelength is,

Ephoton=EE2

  • E2andE are the energy of the second and infinite level
  • Ephoton is energy of the photon,

Substitute (0eV) for E , (3.401eV) for E2 to find Ephoton .

Ephoton=(0eV)(3.401eV)=3.401eV

Thus, the energy of the photon of the shortest wavelength is 3.401eV .

Section 2:

To determine: The shortest wavelength.

Answer: The shortest wavelength is 3.66×107m .

Explanation:

Formula to calculate the wavelength of the photon of the shortest wavelength is,

λ=hcEphoton

  • h is the Planck’s constant
  • c is the speed of light
  • Ephoton is energy of the photon,

From unit conversion,

1eV=1.6×1019J

Substitute 6.63×1034J-s for h , 3×108m/s for c , 3.401eV for Ephoton to find λ .

λ=(6.63×1034J-s)(3×108m/s)(3.4012eV)(1eV1.6×1019J)=3.66×107m

Thus, the shortest wavelength is 3.66×107m .

Conclusion:

Therefore, the shortest wavelength is 3.66×107m

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Students have asked these similar questions
The Balmer series for the hydrogen atom corresponds to electronic transitions that terminate in the state with quantum number n = 2 as shown in Figure P28.19. Consider the photon of longest wavelength corresponding to a transition shown in the figure. Determine (a) its energy and (b) its wavelength. Consider the spectral line of shortest wavelength corresponding to a transition shown in the figure. Find (c) its photon energy and (d) its wavelength. (e) What is the shortest possible wavelength in the Balmer series?
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