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Fall 2011 PHYS 172: Modern Mechanics Lecture 7 – Speed of Sound in a Solid, Buoyancy Read 4.9 – 4.13.

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Presentation on theme: "Fall 2011 PHYS 172: Modern Mechanics Lecture 7 – Speed of Sound in a Solid, Buoyancy Read 4.9 – 4.13."— Presentation transcript:

1 Fall 2011 PHYS 172: Modern Mechanics Lecture 7 – Speed of Sound in a Solid, Buoyancy Read 4.9 – 4.13

2 A desk has a mass of 57.5 kilograms. If the coefficient of static friction between the desk and the floor is 0.92, what force must be used to move the desk from rest?

3 Once the desk above is in motion, what force must be used to keep it moving at a constant velocity if the coefficient of kinetic friction is 0.6133333333333333?

4 A 7 kg object with initial speed = 5 m/s takes 2 seconds to stop due to friction. What is the coefficient of kinetic friction?

5 Derivative form of the Momentum Principle The Momentum Principle The rate of the momentum change is equal to force Works only if force is constant during  t If force changes introduce instantaneous rate of change: The momentum principle

6 Newton’s Second Law Assume nonrelativistic case: (definition of acceleration) Newton’s second law Traditional form of 2 nd Newton’s law (Assume m = const) Newton’s original formulation: The rate of change of amount of body’s motion is proportional to force momentum Momentum principle is the second Newton’s law

7 Spring-mass system: horizontal 1. System: block 2. Apply momentum principle: x y z Equilibrium =0

8 Spring-mass system: Analytical solution Motion along x: p x = p nonrelativistic Differential equation:

9 Spring-mass system: Analytical solution Search solution in form: Angular frequency amplitude t

10 Spring-mass system: period and frequency A -A t Period T: T2T2T Frequency : Angular frequency: [radian/second] A [s] [s -1 ]  [Hz]

11 Static equilibrium x y System is at rest: Can predict s: (system never moves)

12 Spring-mass system: vertical x y Choose origin at equilibrium position s0s0 Apply momentum principle: The same equation and motion in the presence of gravity if you choose origin at equilibrium! Details: 4.14 (p. 167)

13 Speed of sound in solids Qualitatively: Larger , larger v Larger d, larger v Detailed derivation:Speed of sound in a solid

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