In the Figure below, a pool of liquid sodium is sitting in open atmosphere (and somehow not exploding from the moisture in the air) and an absolute pressure measurement device. The measurement device reads an absolute pressure of P2 at the depth of L in the pool. a) Find the pressure difference between P2 and P1, if the P2 reads 5bar. b) Find and state the density of liquid sodium (assume it has a temperature just above the melting point for sodium), include your reference (i.e. website or book citation). c) Using the density of liquid sodium, find the depth (L) of the sodium. d) Calculate the pressure gradient ( ) e) Plot the pressure distribution from the P2 and P1. dP Figure 1: A 2-D pool of Sodium on Earth that magically is keeping all of it's liquid inside even though it has no front and back sides.

EGMN 301 - Fluid Mechanics

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In the Figure below, a pool of liquid sodium is sitting in open atmosphere (and somehow not exploding from the moisture in the air) and an absolute pressure measurement device. The measurement device reads an absolute pressure of P2 at the depth of L in the pool. a) Find the pressure difference between P2 and P1, if the P2 reads 5bar. b) Find and state the density of liquid sodium (assume it has a temperature just above the melting point for sodium), include your reference (i.e. website or book citation). c) Using the density of liquid sodium, find the depth (L) of the sodium. d) Calculate the pressure gradient () dP e) Plot the pressure distribution from the P2 and P1. Figure 1: A 2-D pool of Sodium on Earth that magically is keeping all of it's liquid inside even though it has no front and back sides.