When you are swimming at the bottom of a pool, the water above and around you exerts force on your eardrum. Calculate theforce (in N) exerted on your eardrum when you are at the bottom of a pool that is 5.0 m deep. Assume that the area of youreardrum is 1 cm^2 and the density of water is 1000 kg/m^3 (10,000 cm^2 = 1m^2) (Ans: 5N)To solve this, which of the following equation/s should you use (check as many that best applies)O Q = mLO F1_ F2A1A2O F=maO A1V1= A2V2O fEdA = denc€0Ο ΔL αLo Δ .O du = dQ - dW or AU= Q- WO PV = nRTPz +pgh2 + pv=P1+pgh1+FOp=O as-SO P= pghO e=!Tc1-TnOw-ovV2W =O Fp = P fluidgV submergedOp =m/VF =4πεοO Tk = T+273.15K To solve this, which of the following equation/s should you use (check as many that best applies)O Q = mLO F1_ F2A1A2O F=maO A,V1= A2V2O fEdA = Ienc€0Ο ΔL Lo Δ .O du = dQ- dW or AU = Q-WO PV = nRTPz + pghz + 글p을 =P1+ pghi +FOp=AO as = SO P=pghTcO e=1ThV2W =O Fp= P fluidgV submergedOp =m/V1 ]9192]F =4 TIEOO Tk=Tc+273.15KO Q= mcATO E=F/q

When you are swimming at the bottom of a pool, the water above and around you exerts force on your eardrum. Calculate the force (in N) exerted on your eardrum when you are at the bottom of a pool that is 5.0 m deep. Assume that the area of your eardrum is 1 cm^2 and the density of water is 1000 kg/m^3 (10,000 cm^2 = 1m^2) (Ans: 5N) To solve this, which of the following equation/s should you use (check as many that best applies) O Q= mL O F1 F2 A1 A2 F=ma O A1V1= A2V2 O GEDA = 9 enc €0 O AL= «LOAT O du = dQ - dW or AU= Q- W O PV = nRT P2 + pgh2 +pv=P1+pgh1 Op= A O as- S9 O P= pgh Tc e = 1- Th V2 AP. Ow= O Fp = P fluidgV submerged Ορ-m/V 1 |4192| F = 4 TEO O Tk=T+273.15K

When you are swimming at the bottom of a pool, the water above and around you exerts force on your eardrum. Calculate the force (in N) exerted on your eardrum when you are at the bottom of a pool that is 5.0 m deep. Assume that the area of your eardrum is 1 cm^2 and the density of water is 1000 kg/m^3 (10,000 cm^2 = 1m^2) (Ans: 5N) To solve this, which of the following equation/s should you use (check as many that best applies) O Q= mL O F1 F2 A1 A2 F=ma O A1V1= A2V2 O GEDA = 9 enc €0 O AL= «LOAT O du = dQ - dW or AU= Q- W O PV = nRT P2 + pgh2 +pv=P1+pgh1 Op= A O as- S9 O P= pgh Tc e = 1- Th V2 AP. Ow= O Fp = P fluidgV submerged Ορ-m/V 1 |4192| F = 4 TEO O Tk=T+273.15K

Principles of Physics: A Calculus-Based Text

5th Edition

ISBN:9781133104261

Author:Raymond A. Serway, John W. Jewett

Publisher:Raymond A. Serway, John W. Jewett

Chapter14: Superposition And Standing Waves

Section: Chapter Questions

Problem 38P: As shown in Figure P14.37, water is pumped into a tall, vertical cylinder at a volume flow rate R....

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