A 2000 Hz sound wave passes through a wall with two narrow openings 30 cm apart. If sound travels on average 355 m/s, find the following. (a) What is the angle of the first order maximum? 36.27 (b) Find the slit separation when you replace the sound wave with a 2.30 cm microwave, and the angle of the first order maximum remains unchanged. 3.8878 How do you find the angle of a diffraction pattern, given wavelength? m (c) If the slit separation is 1.00 um, what frequency of light gives the same first order maximum angle? 6.0007e-8 X How do you find the angle of a diffraction pattern, given wavelength? Hz

A 2000 Hz sound wave passes through a wall with two narrow openings 30 cm apart. If sound travels on average 355 m/s, find the following. (a) What is the angle of the first order maximum? 36.27 (b) Find the slit separation when you replace the sound wave with a 2.30 cm microwave, and the angle of the first order maximum remains unchanged. 3.8878 How do you find the angle of a diffraction pattern, given wavelength? m (c) If the slit separation is 1.00 um, what frequency of light gives the same first order maximum angle? 6.0007e-8 X How do you find the angle of a diffraction pattern, given wavelength? Hz

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A 2000 Hz sound wave passes through a wall with two narrow openings 30 cm apart. If sound travels on average 355 m/s, find
the following.
(a) What is the angle of the first order maximum?
36.27
(b) Find the slit separation when you replace the sound wave with a 2.30 cm microwave, and the angle of the first order
maximum remains unchanged.
3.8878
How do you find the angle of a diffraction pattern, given wavelength? m
(c) If the slit separation is 1.00 µm, what frequency of light gives the same first order maximum angle?
6.0007e-8X
How do you find the angle of a diffraction pattern, given wavelength? Hz
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