Homework Solution - Standing Waves and Pressure in a Closed Tube

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The discussion centers on a physics problem involving a closed vertical tube filled with mercury, where the goal is to find the absolute pressure at the bottom of the mercury column. The fundamental frequency of the shortened air-filled tube is set to equal the third harmonic of the original tube. Participants clarify that the pressure at the bottom of the mercury column is not directly related to the standing wave equations provided, specifically Fn = nv/4L. Instead, the solution requires using the density of mercury to calculate the pressure independently. The final answer for the absolute pressure is 1.68 x 10^5 Pa.
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Homework Statement



A vertical tube is closed at one end and open to air at the other end. The air pressure is 1.01 x 10^5 Pa. The tube has a length of 0.75 m. Mercury (mass density = 13,600 kg/m3) is poured into it to shorten the effective length for standing waves. What is the absolute pressure at the bottom of the mercury column, when the fundamental frequency of the shortened air-filled tube is equal to the third harmonic of the original tube?
ANS: 1.68 x 10^5 Pa

Homework Equations


Ive been given the equations Fn = nv/4L for tubes with one open end, although I can't seem to find any way to relate pressure and waves, can anyone help?
 
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hi 3ephemeralwnd! :smile:

(try using the X2 icon just above the Reply box :wink:)
3ephemeralwnd said:
Ive been given the equations Fn = nv/4L for tubes with one open end, although I can't seem to find any way to relate pressure and waves, can anyone help?

the pressure at the bottom of the mercury has nothing to do with the wave between the top of the mercury and the open end …

it's just a cute way of asking two totally unrelated :rolleyes: questions at once! :biggrin:

(so just use the density of mercury :wink:)
 

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