Part a Answer: [tex] 9.16 \times 10^4 Pa [/tex] Absolute pressure (P) = atmospheric pressure [tex]P_o[/tex] + pressure due to weight of fluid above it [tex]\rho g h[/tex]. [tex]P=P_o+ \rho g h[/tex] g is acceleration due to gravity [tex]= 9.8 m/s^2[/tex] h is height of the water column above it =2.02 m [tex]\rho [/tex] is density of water [tex] = 1000 kg/m^3 [/tex]
[tex]P_o [/tex] is atmospheric pressure = 0.709 atm.
Substitute the values:
[tex]P= 0.709 \times 101325 Pa + 1000 \times 9.8 \times 2.02 Pa[/tex] Because: [tex]1 atm = 101325 Pa[/tex] Hence, absolute pressure at the bottom is [tex] 9.16 \times 10^4 Pa [/tex] Part b Answer: 104.34 Pa Radius of the pool = 4.73 m Increase in the absolute pressure at the bottom = Absolute pressure with two people in the pool - Absolute pressure without them = Pressure due to two people [tex] P'-P =\frac {Mg}{A} = \frac {Mg}{\pi r^2} [/tex] Where M is the combined mass of the person, g is the acceleration of gravity and r is the radius of the pool. [tex] \Delta P=\frac {158 \times 9.8}{\pi {4.73}^2} Pa = 104.34 Pa [/tex]
