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White light dispersed by a prism has wavelengths ranging from 400 nanometers to 700 nanometers.
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The 400-nanometer-wavelength light has a minimum angle of deviation of 22.9 degrees.
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The 700-nanometer-wavelength light has a minimum angle of deviation of 22.1 degrees.
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And the 550-nanometer-wavelength light has a minimum angle of deviation of 22.5 degrees.
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What is the dispersive power of the prism?
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Give your answer to three decimal places.
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So in this question, we have a prism, which we’ll represent by this triangle.
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White light enters this prism and is dispersed because the different wavelengths of light that make up the white light are deviated by different amounts when they pass through the prism.
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For example, we see that red light, which is the longest wavelength light, is deviated much less than blue light, which has a much shorter wavelength.
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The dispersive power of a prism is a number which tells us how much the prism spreads out white light, and this is exactly what we’re asked to calculate in this question.
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The larger the dispersive power of the prism, the more the prism spreads out or disperses white light.
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We represent the dispersive power of a prism with the Greek letter 𝜔, along with a subscript 𝛼.
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We put an 𝛼 in the subscript because 𝛼 is the symbol we usually use to denote the angle of deviation for a particular wavelength of light.
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If we draw a dashed line to show the direction the white light was traveling when it entered the prism, then the angle of deviation for a given wavelength of light is the angle between this dashed line and the direction that wavelength of light is traveling when it leaves the prism.
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For example, the angle of deviation for red light is shown here.
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And we can label this 𝛼 subscript red.
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We can also see that the angle of deviation for blue light is much larger.
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And we can label this angle 𝛼 subscript blue.
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Let’s now recall the formula that lets us calculate the dispersive power of a prism using the angles of deviation for the different wavelengths of light passing through the prism.
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This formula is written like this and is often given in terms of the symbols 𝛼 max and 𝛼 min, where 𝛼 max is the largest angle of deviation for the prism and 𝛼 min is the smallest angle of deviation for the prism.
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In terms of these two quantities, the formula for the dispersive power of a prism is written as a fraction.
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And on the top of that fraction, we have 𝛼 max minus 𝛼 min.
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So this is the difference between the largest angle of deviation and the smallest angle of deviation.
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And on the bottom of the fraction, we have 𝛼 max plus 𝛼 min all divided by two, which actually gives us the average angle of deviation for the prism.
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So to calculate the dispersive power for our prism, we just need to identify 𝛼 max and 𝛼 min for our prism and then substitute these values into the formula for 𝜔 𝛼.
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The question tells us that the longest wavelength of light passing through the prism is 700 nanometers.
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And we’re also told that this wavelength of light will experience an angle of deviation of at least 22.1 degrees.
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700-nanometer light actually corresponds to red light.
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And since we know that this is the longest wavelength of light passing through the prism, we know it will be deviated by the smallest or minimum amount.
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This is exactly what we saw in our original sketch of a prism, and it means that we can identify the minimum angle of deviation with the angle of deviation for red light.
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Since we’re told this value in the question, we can then simply write that 𝛼 min is equal to 22.1 degrees.
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We’re also told that the shortest wavelength light passing through the prism has a wavelength of 400 nanometers and that this light will experience an angle of deviation of at least 22.9 degrees.
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This wavelength of light corresponds to blue light.
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And just as we saw earlier, blue light will experience the maximum deviation out of all the colors that make up the white light.
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This means we can say that the maximum angle of deviation is the same as the angle of deviation for blue light.
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And again, since we’re told this value in the question, we can say that 𝛼 max is equal to 22.9 degrees.
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At this point, all we need to do is substitute the values we’ve just found for 𝛼 min and 𝛼 max into the formula we have for the dispersive power 𝜔 𝛼.
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Doing this gives us this formula here.
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In the numerator, we had 𝛼 max minus 𝛼 min, and this reads 22.9 degrees minus 22.1 degrees.
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And in the denominator, we have 𝛼 max plus 𝛼 min divided by two, which now reads 22.9 degrees plus 22.1 degrees all divided by two.
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If we now calculate the top and bottom of this fraction separately, we find that 𝜔 𝛼 is equal to 0.8 degrees divided by 22.5 degrees.
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We can note that the denominator of this fraction 22.5 degrees, which we found by calculating the average value of the angles of deviation of the prism, is also the angle of deviation for light with a wavelength of 550 nanometers.
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And we’re told this in the question.
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This is because 550 is the average of 400 and 700 nanometers.
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And so we see that the average of the angles of deviation of the prism is the same as the angle of deviation for the average wavelengths of light passing through the prism.
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And since we were told the angle of deviation for the average wavelengths of light passing through the prism, we could’ve used this as a shortcut to know the denominator of this formula.
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Either way, all that’s left to do now is calculate the fraction 0.8 degrees divided by 22.5 degrees.
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If we do this calculation, we find that 𝜔 𝛼 is equal to 0.0355 and so on.
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Notice that this number doesn’t have any units attached to it because the degrees on the top and bottom of the fraction have canceled out.
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Finally, we just need to round our answer to three decimal places as we’re told in the question.
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Doing this gives us our final answer to the question.
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We found that the dispersive power of the prism, 𝜔 α, is equal to 0.036.