(II) White light passes through a 640-slit/ mm diffraction gra...

Question

(II) White light passes through a 640-slit/ mm diffraction grating. First-order and second-order visible spectra (“rainbows”) appear on the wall 32 cm away as shown in Fig. 35–40. Determine the widths ℓ₁ and ℓ₂ of the two “rainbows” (400 nm to 700 nm). In which order is the “rainbow” dispersed over a larger distance?

Accepted Answer

Welcome back. Everyone in an optics experiment. A diffraction grating with 660 slits per millimeter is used to analyze the visible light spectrum emitted by a source. The visible light ranges from lambda, one equals 450 nanometers blue to lambda, two equals 650 nanometers orange. The diffraction pattern is projected onto a screen located L equals 50 centimeters away. First, we want to calculate the distances covered by the first order H one and the second order H two spectra on the screen. And second, we want to determine which diffraction order spans are greater width. Here we have a diagram showing our diffraction grating and our lights. And for our answer choices, A says that the distance covered by the first order spectra is 9.2 centimeters by the second order spectra is 49 centimeters. And that the first order spectrum spans a greater width B says they are 9.2 centimeters, 47 centimeters. And the second order spectrum c 8.1 centimeters 49 centimeters. And the first order spectrum and the D 8.1 centimeters 47 centimeters. And the second order spectrum. Now how are we going to figure out the first part of this problem? That is the distances that have been covered by the first order and second order spectra on the screen. Well, so far, there's a bit of information that we are already given. Now, we know that our diffraction grating N is 660 slits per millimeter or we can write it as 660 multiplied by 10 to the third slits per meter. OK. And if this is our diffraction grating, then this means that our split spacing D which is the reciprocal of our diffraction grating is going to be equal to one divided by 660 multiplied by 10 to the third slits per meter or 1.515 multiplied by 10 to the negative 6 m. OK. Now, we also know that our blue light has a wavelength of 450 nanometers while our orange light has a wavelength of 650 nanometers. And our screen distance is L 50 centimeters or 0.5 m. So we can write 0.5 m here. And we also know that we're looking at our first order diffraction m equals one and our second order diffraction M equals two. OK. So I should probably make a note of that beside them. This is the second order. Now, what do we know about the distance covered by the first order? Is it related to any of the information we already have. Well recall, OK, that the distance covered, let's call that distance is going to be equal to the difference. OK. It's going to be equal to the difference between the displacement on the screen for a for a given wavelength. So in other words, it's going to be equal to the difference between yy sorry, the displacement for our orange light compared to the displacement for our blue light. Yb. Now, what do we know about those displacements on the screen? Well, we also know that the displacement Y on the screen for a given wavelength is equal to L multiplied by the tangent of theta. OK. Where theta is our diffraction angle for a given order. Now again, we know what the value of L is, but we don't know the value of theta for our orange light or for our red light for its respective order. So we'll need to figure that out. But we also know that there's a way for us to find our diffraction angle because the diffraction angle for a given order M is equal is can be given by the formula sine theta where theta is the fraction, the diffraction angle equals M lambda divided by D because we can use this then to find our angle by finding the arc sign of M lambda divided by D. So we can work our way up to figure out our, our, our distances for our, for both of our orders. Because all we need to do is to first find the diffraction angle, then substitute it into our formula for our screen displacement. And thus, we will be able to solve for the distance between our, the distance between our lights. OK? Or the width of our spectrums. So let's go ahead and start for the first order spectrum. Let's apply this idea. OK. Now, when let me put this in blue here or let me put it in red when M equals one, OK? For starters then for or blue light, OK? Or, or blue light, let's call that anger theta B, the diffraction angle will be equal to M multiplied by the wavelength of our blue light lambda one divided by the value of D where we know D represents our split spacing and it is the same, sorry. Actually, it's the inverse or the arc sign of that expression. My apologies here. OK? So let me just fix that. So that means to solve we can substitute our values. So that's going to be the arc sign of one multiplied by 4.5 multiplied by 10 to the negative seventh meters. OK? All divided by 1.515 multiplied by 10 to the negative 6 m. I know when we go ahead and divide, then we should get this angle to be approximately equal to 17.33 degrees. Likewise for our orange light, OK. Our D fraction angle is going to be equal to the inverse sine of M Lambda two divided by D OK, which is gonna be the inverse sine of one multiplied by 6.5 multiplied by 10 to the negative 7 m 650 nanometers divided by 1.515 multiplied by 10 to the negative sixth, which again is gonna be equal to approximately 25.4 degrees. Now that we have our angles, then we can go ahead and solve for the distance because now we know that our distance H which equals yo minus YB is going to be equal to L 10 data O OK. Minus L tan the B. Well, of course, we can factor OL. So that's L multiplied by 10 theta O minus 10 theta B. OK? And now we can go ahead to substitute. And so OK, because if we do that, that means it's gonna be equal to 0.5 m multiplied by the tangent of or the angle four or orange light 25.4 degrees minus the tangent four or blue light 17.3 degrees. I know when we go ahead and solve here, let's call this H one because we're talking about our 1st, 1st order when M equals one, then we get the distance, we get the widths or our first order spectrum to be equal to 0.081 m. Or we can write that as approximately 8.1 centimeters. Thus, this is going to be our width for the first order spectrum. How about the second order spectrum? Well, let's try to figure it out. So now we're basically gonna do the same thing, but we're trying to find it when M equals two. So now when M equals two, OK, then the diffraction angle floor blue light again, it's equal to the sine inverse of M two multiplied by our wavelength 4.5 multiplied by 10 to the negative seventh meters. OK. Divided by 1.515 multiplied by 10 to the negative sixth meters. OK? And now when we go ahead and solve here, then we should get it to be 36.44 degrees. Likewise, that means our angle for our orange light is going to be equal to the inverse sine. OK. Two multiplied by 6.5 multiplied by 10th of the negative seventh meters divided by 1.515 multiplied by 10 to the negative 6 m which is equal to 59.09 degrees. OK. So now we have both of our angles and we can use it to solve our two because now this means two or this the width of our second order spectrum, then it is gonna be 0.5 m multiplied by the tangent of 59.09 degrees minus the tangent of 36.44 degrees, which is going to be equal to 0.466 m. Or approximately 47 centimeters. So now we notice that the distance for our first order spectrum is the distance covered. Sorry by the first order spectrum is 8.1 centimeters by the second order spectrum is 47 centimeters. And thus, we can tell that our second order diffraction spectrum spans a greater width than the first order diffraction spectrum. Therefore, if we go back to our answers, that tells us D is the correct answer. Thanks a lot for watching everyone. I hope this video helped.

Key Concepts

Diffraction Grating

Order of Diffraction

Wavelength and Color Dispersion

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