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Chapter 28 Relativity.

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Presentation on theme: "Chapter 28 Relativity."— Presentation transcript:

1 Chapter 28 Relativity

2 Relativistic Momentum
The basic conservation laws for momentum and energy can not be violated due to relativity. Newton’s equation for momentum (mv) must be changed as follows to account for relativity: Relativistic momentum: mo is the proper mass, often called the rest mass. Note that for v=0, this equation reduces to Newton’s equation.

3 The speed of light is an ultimate speed!
Relativistic Mass If momentum is to be conserved, the relativistic mass m must be consistent with the following equation: Relativistic mass: Note that as an object is accelerated by a resultant force, its mass increases, which requires even more force. This means that: The speed of light is an ultimate speed!

4 The mass has increased by 67% !
Example 3: The rest mass of an electron is 9.1 x kg. What is the relativistic mass if its velocity is 0.8c ? - 0.8c mo = 9.1 x kg The mass has increased by 67% ! m = 15.2 x kg

5 Mass and Energy Prior to the theory of relativity, scientists considered mass and energy as separate quantities, each of which must be conserved. Now mass and energy must be considered as the same quantity. We may express the mass of a baseball in joules or its energy in kilograms! The motion adds to the mass-energy.

6 Total Relativistic Energy
The general formula for the relativistic total energy involves the rest mass mo and the relativistic momentum p = mv. Total Energy, E Including Momentum For a particle with zero momentum p = 0: E = moc2 For an EM wave, m0 = 0, and E simplifies to: E = pc

7 The zero subscript refers to proper or rest values.
Mass and Energy (Cont.) The conversion factor between mass m and energy E is: Eo = moc2 The zero subscript refers to proper or rest values. 1 kg A 1-kg block on a table has an energy Eo and mass mo relative to table: Eo = 9 x 1016 J Eo = (1 kg)(3 x 108 m/s)2 If the 1-kg block is in relative motion, its kinetic energy adds to the total energy.

8 THE TOTAL ENERGY OF AN OBJECT
Rest energy of an object Eo = rest energy, E= total energy

9 Example 8 The Sun is Losing Mass
The sun radiates electromagnetic energy at a rate of 3.92x1026W. What is the change in the sun’s mass during each second that it is radiating energy? What fraction of the sun’s mass is lost during a human lifetime of 75 years.

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11 Relativistic Addition of Velocities
For a general situation, the relative velocities are related by the velocity addition formula. At speeds much below the speed of light, this is equivalent to our current understanding of addition of velocities

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