Consider a beam of electrons in a vacuum, passing through a very narrow slit of width 2.00 µm. The electrons then head toward an array of detectors a distance 1.029 m away. These detectors indicate a diffraction pattern, with a broad maximum of electron intensity (i.e., the number of electrons received in a certain area over a certain period of time) with minima of electron intensity on either side, spaced 0.498 cm from the center of the pattern. What is the wavelength A of one of the electrons in this beam? Recall that the location of the first intensity minima in a single slit diffraction pattern for light is y = L^/a, where L is the distance to the screen (detector) and a is the width of the slit The derivation of this formula was based entirely upon the wave nature of light, so by de Broglie's hypothesis it will also apply to the case of electron waves. Express your answer in meters to three significant figures. m Submit Request Answer

College Physics
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Chapter1: Units, Trigonometry. And Vectors
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Problem 1CQ: Estimate the order of magnitude of the length, in meters, of each of the following; (a) a mouse, (b)...
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Part C
Consider a beam of electrons in a vacuum, passing through a very narrow slit of width
2.00 µm. The electrons then head toward an array of detectors a distance 1.029 m away.
These detectors indicate a diffraction pattern, with a broad maximum of electron intensity
(i.e., the number of electrons received in a certain area over a certain period of time) with
minima of electron intensity on either side, spaced 0.498 cm from the center of the
pattern. What is the wavelength of one of the electrons in this beam? Recall that the
location of the first intensity minima in a single slit diffraction pattern for light is
y = LX/a, where L is the distance to the screen (detector) and a is the width of the slit.
The derivation of this formula was based entirely upon the wave nature of light, so by de
Broglie's hypothesis it will also apply to the case of electron waves.
Express your answer in meters to three significant figures.
ΑΣφ
=
Submit
Request Answer
Transcribed Image Text:Part C Consider a beam of electrons in a vacuum, passing through a very narrow slit of width 2.00 µm. The electrons then head toward an array of detectors a distance 1.029 m away. These detectors indicate a diffraction pattern, with a broad maximum of electron intensity (i.e., the number of electrons received in a certain area over a certain period of time) with minima of electron intensity on either side, spaced 0.498 cm from the center of the pattern. What is the wavelength of one of the electrons in this beam? Recall that the location of the first intensity minima in a single slit diffraction pattern for light is y = LX/a, where L is the distance to the screen (detector) and a is the width of the slit. The derivation of this formula was based entirely upon the wave nature of light, so by de Broglie's hypothesis it will also apply to the case of electron waves. Express your answer in meters to three significant figures. ΑΣφ = Submit Request Answer
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