PHYSICS
PHYSICS
5th Edition
ISBN: 2818440038631
Author: GIAMBATTISTA
Publisher: MCG
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Chapter 25, Problem 45P

(a)

To determine

The number of orders of lines that can be seen with the grating.

(a)

Expert Solution
Check Mark

Answer to Problem 45P

The number of orders of lines that can be seen with the grating is 3_.

Explanation of Solution

Given that the width of the grating is 1.600cm, the number of slits is 12000, and the wavelengths of light are λa=440.000nm and λb=440.936nm.

Write the expression for the slit width of the grating.

  d=width of gratingtotal number of slits                                                                                     (I)

Here, d is the slit width.

Write the expression for the diffraction maxima using grating.

  dsinθ=mλ                                                                                                    (II)

Here, θ is the angle of diffraction, λ is the wavelength of light, and m is the order of diffraction.

Deduce the number of orders that can be seen, from equation (II).

  mdsinθλ                                                                                                      (III)

The maximum number of orders is obtained for θ=90° (since sinθ=90°).

Conclusion:

Substitute 1.600cm for width of grating, and 12000 for the total number of slits in equation (I) to find d.

  d=1.600cm12000=1.600cm×1m100cm12000=1.333×106m

Substitute 1.333×106m for d, 90° for θ, and 440.000nm for λ in equation (III) to find m.

  m(1.333×106m)sin90°440.000nm=3.024

Since m must be an integer, it can be taken as m=3.

Therefore, the number of orders of lines that can be seen with the grating is 3_.

(b)

To determine

The angular separation θbθa between the lines in each order.

(b)

Expert Solution
Check Mark

Answer to Problem 45P

The angular separation θbθa between the lines in each order are θb1θa1=0.04°_, θb2θa2=0.11°_, and θb3θa3=0.91°_.

Explanation of Solution

Given that the width of the grating is 1.600cm, the number of slits is 12000, and the wavelengths of light are λa=440.000nm and λb=440.936nm.

Solve equation (II) for θ.

  θ=sin1(mλd)                                                                                          (IV)

The angles corresponding to each wavelengths for each orders can be computed and their difference gives the angular separation.

Conclusion:

The value of 1/d can be computed from equation (I) as,

  1d=120001.600cm=120001.600cm×1m100cm=7.500×105/m

Substitute 1 for m, 440.000nm for λ, and 7.500×105/m for 1/d in equation (IV) to find θ corresponding to order 1 of λa, (θa1).

  θa1=sin1[(1)(440.000nm)(7.500×105/m)]=sin1[(1)(440.000nm×1m1×109m)(7.500×105/m)]=19.27°

Substitute 2 for m, 440.000nm for λ, and 7.500×105/m for 1/d in equation (IV) to find θ corresponding to order 2 of λa, (θa2)

  θa2=sin1[(2)(440.000nm)(7.500×105/m)]=sin1[(2)(440.000nm×1m1×109m)(7.500×105/m)]=41.30°

Substitute 3 for m, 440.000nm for λ, and 7.500×105/m for 1/d in equation (IV) to find θ corresponding to order 3 of λa, (θa3)

  θa3=sin1[(3)(440.000nm)(7.500×105/m)]=sin1[(3)(440.000nm×1m1×109m)(7.500×105/m)]=81.89°

Substitute 1 for m, 440.936nm for λ, and 7.500×105/m for 1/d in equation (IV) to find θ corresponding to order 1 of λb, (θb1).

  θb1=sin1[(1)(440.936nm)(7.500×105/m)]=sin1[(1)(440.936nm×1m1×109m)(7.500×105/m)]=19.31°

Substitute 2 for m, 440.936nm for λ, and 7.500×105/m for 1/d in equation (IV) to find θ corresponding to order 2 of λb, (θb2)

  θb2=sin1[(2)(440.936nm)(7.500×105/m)]=sin1[(2)(440.936nm×1m1×109m)(7.500×105/m)]=41.41°

Substitute 3 for m, 440.936nm for λ, and 7.500×105/m for 1/d in equation (IV) to find θ corresponding to order 3 of λb, (θb3)

  θb3=sin1[(3)(440.936nm)(7.500×105/m)]=sin1[(3)(440.936nm×1m1×109m)(7.500×105/m)]=82.80°

Compute the angular separation for each orders.

  θb1θa1=19.31°19.27°=0.04°

  θb2θa2=41.41°41.30°=0.11°

  θb3θb3=82.80°81.89°=0.91°

Therefore, the angular separation θbθa between the lines in each order are θb1θa1=0.04°_, θb2θa2=0.11°_, and θb3θa3=0.91°_.

(c)

To determine

The order of the spectrum which best resolves the two lines.

(c)

Expert Solution
Check Mark

Answer to Problem 45P

The third order spectrum best resolves the two lines.

Explanation of Solution

The angular separation for different orders of the spectrum are obtained as θb1θa1=0.04°, θb2θa2=0.11°, and θb3θa3=0.91°.

The higher resolution corresponds to larger angular separation in the diffraction process. Among the obtained values of the angular separations, the third order spectrum has the largest angular separation. Thus, the two lines are best resolved in the third-order spectrum.

Conclusion:

Therefore, the third order spectrum best resolves the two lines.

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