General Physics (PHY 2140) Lecture 26 Modern Physics Relativity Relativistic momentum, energy, … General relativity http://www.physics.wayne.edu/~apetrov/PHY2140/ Chapter 26 9/19/2018

If you want to know your progress so far, please send me an email request at apetrov@physics.wayne.edu 9/19/2018

Lightning Review Last lecture: Modern physics Time dilation, length contraction Review Problem: A planar electromagnetic wave is propagating through space. Its electric field vector is given by E = Eo cos(kz – wt) x, where x is a unit vector in the positive direction of Ox axis. Its magnetic field vector is 1. B = Bo cos(kz – wt) y 2. B = Bo cos(ky – wt) z 3. B = Bo cos(ky – wt) x 4. B = Bo cos(kz – wt) z where y and z are unit vectors in the positive directions of Oy and Oz axes respectively. 9/19/2018

Reminder (for those who don’t read syllabus) Reading Quizzes (bonus 5%): It is important for you to come to class prepared, i.e. be familiar with the material to be presented. To test your preparedness, a simple five-minute quiz, testing your qualitative familiarity with the material to be discussed in class, will be given at the beginning of some of the classes. No make-up reading quizzes will be given. There could be one today… … but then again… 9/19/2018

Problem: relativistic pion The average lifetime of a p meson in its own frame of reference (i.e., the proper lifetime) is 2.6 × 10–8 s. If the meson moves with a speed of 0.98c, what is its mean lifetime as measured by an observer on Earth and the average distance it travels before decaying as measured by an observer on Earth? What distance would it travel if time dilation did not occur? 9/19/2018

(c) What distance would it travel if time dilation did not occur? The average lifetime of a p meson in its own frame of reference (i.e., the proper lifetime) is 2.6 × 10–8 s. If the meson moves with a speed of 0.98c, what is (a) its mean lifetime as measured by an observer on Earth and (b) the average distance it travels before decaying as measured by an observer on Earth? (c) What distance would it travel if time dilation did not occur? Recall that the time measured by observer on Earth will be longer then the proper time. Thus for the lifetime Given: v = 0.98 c tp = 2.6 × 10–8 s Find: t = ? d = ? dn =? Thus, at this speed it will travel If special relativity were wrong, it would only fly about 9/19/2018

Problem: space flight In 1963 when Mercury astronaut Gordon Cooper orbited Earth 22 times, the press stated that for each orbit he aged 2 millionths of a second less than if he had remained on Earth. Assuming that he was 160 km above Earth in a circular orbit, determine the time difference between someone on Earth and the orbiting astronaut for the 22 orbits. You will need to use the approximation for x << 1 (b) Did the press report accurate information? Explain. 9/19/2018

Length Contraction The measured distance between two points depends on the frame of reference of the observer The proper length, Lp, of an object is the length of the object measured by someone at rest relative to the object The length of an object measured in a reference frame that is moving with respect to the object is always less than the proper length This effect is known as length contraction 9/19/2018

Problem: weird cube A box is cubical with sides of proper lengths L1 = L2 = L3= 2 m, when viewed in its own rest frame. If this block moves parallel to one of its edges with a speed of 0.80c past an observer, what shape does it appear to have to this observer, and what is the length of each side as measured by this observer? 9/19/2018

A box is cubical with sides of proper lengths L1 = L2 = L3= 2 m, when viewed in its own rest frame. If this block moves parallel to one of its edges with a speed of 0.80c past an observer, (a) what shape does it appear to have to this observer, and (b) what is the length of each side as measured by this observer? Recall that only the length in the direction of motion is contracted, so Given: v = 0.8 c Lip = 2.0 m Find: shape Li=? Thus, numerically, 9/19/2018

Relativistic Definitions To properly describe the motion of particles within special relativity, Newton’s laws of motion and the definitions of momentum and energy need to be generalized These generalized definitions reduce to the classical ones when the speed is much less than c 9/19/2018

26.7 Relativistic Momentum To account for conservation of momentum in all inertial frames, the definition must be modified v is the speed of the particle, m is its mass as measured by an observer at rest with respect to the mass When v << c, the denominator approaches 1 and so p approaches mv 9/19/2018

Problem: particle decay An unstable particle at rest breaks up into two fragments of unequal mass. The mass of the lighter fragment is 2.50 × 10–28 kg, and that of the heavier fragment is 1.67 × 10–27 kg. If the lighter fragment has a speed of 0.893c after the breakup, what is the speed of the heavier fragment? 9/19/2018

For the heavier fragment, An unstable particle at rest breaks up into two fragments of unequal mass. The mass of the lighter fragment is 2.50 × 10–28 kg, and that of the heavier fragment is 1.67 × 10–27 kg. If the lighter fragment has a speed of 0.893c after the breakup, what is the speed of the heavier fragment? Momentum must be conserved, so the momenta of the two fragments must add to zero. Thus, their magnitudes must be equal, or Given: v1 = 0.8 c m1=2.50×10–28 kg m2=1.67×10–27 kg Find: v2 = ? For the heavier fragment, which reduces to and yields 9/19/2018

26.8 Relativistic Addition of Velocities Galilean relative velocities cannot be applied to objects moving near the speed of light Einstein’s modification is The denominator is a correction based on length contraction and time dilation 9/19/2018

Problem: more spaceships… A spaceship travels at 0.750c relative to Earth. If the spaceship fires a small rocket in the forward direction, how fast (relative to the ship) must it be fired for it to travel at 0.950c relative to Earth? 9/19/2018

A spaceship travels at 0. 750c relative to Earth A spaceship travels at 0.750c relative to Earth. If the spaceship fires a small rocket in the forward direction, how fast (relative to the ship) must it be fired for it to travel at 0.950c relative to Earth? Since vES = -VSE = velocity of Earth relative to ship, the relativistic velocity addition equation gives Given: vSE = 0.750 c vRE = 0.950 c Find: vRS = ? 9/19/2018

26.9 Relativistic Energy The definition of kinetic energy requires modification in relativistic mechanics KE = mc2 – mc2 The term mc2 is called the rest energy of the object and is independent of its speed The term mc2 is the total energy, E, of the object and depends on its speed and its rest energy 9/19/2018

Relativistic Energy – Consequences A particle has energy by virtue of its mass alone A stationary particle with zero kinetic energy has an energy proportional to its inertial mass E = mc2 The mass of a particle may be completely convertible to energy and pure energy may be converted to particles 9/19/2018

Energy and Relativistic Momentum It is useful to have an expression relating total energy, E, to the relativistic momentum, p E2 = p2c2 + (mc2)2 When the particle is at rest, p = 0 and E = mc2 Massless particles (m = 0) have E = pc This is also used to express masses in energy units mass of an electron = 9.11 x 10-31 kg = 0.511 MeV Conversion: 1 u = 929.494 MeV/c2 9/19/2018

QUICK QUIZ A photon is reflected from a mirror. True or false: (a) Because a photon has a zero mass, it does not exert a force on the mirror. (b) Although the photon has energy, it cannot transfer any energy to the surface because it has zero mass. (c) The photon carries momentum, and when it reflects off the mirror, it undergoes a change in momentum and exerts a force on the mirror. (d) Although the photon carries momentum, its change in momentum is zero when it reflects from the mirror, so it cannot exert a force on the mirror. False True 9/19/2018

Example 1: Pair Production An electron and a positron are produced and the photon disappears A positron is the antiparticle of the electron, same mass but opposite charge Energy, momentum, and charge must be conserved during the process The minimum energy required is 2me = 1.04 MeV 9/19/2018

Example 2: Pair Annihilation In pair annihilation, an electron-positron pair produces two photons The inverse of pair production It is impossible to create a single photon Momentum must be conserved 9/19/2018

26.10 General relativity: Mass – Inertial vs. Gravitational Mass has a gravitational attraction for other masses Mass has an inertial property that resists acceleration Fi = mi a The value of G was chosen to make the values of mg and mi equal 9/19/2018

Einstein’s Reasoning Concerning Mass That mg and mi were directly proportional was evidence for a basic connection between them No mechanical experiment could distinguish between the two He extended the idea to no experiment of any type could distinguish the two masses 9/19/2018

Postulates of General Relativity All laws of nature must have the same form for observers in any frame of reference, whether accelerated or not In the vicinity of any given point, a gravitational field is equivalent to an accelerated frame of reference without a gravitational field This is the principle of equivalence 9/19/2018

Implications of General Relativity Gravitational mass and inertial mass are not just proportional, but completely equivalent A clock in the presence of gravity runs more slowly than one where gravity is negligible The frequencies of radiation emitted by atoms in a strong gravitational field are shifted to lower frequencies This has been detected in the spectral lines emitted by atoms in massive stars 9/19/2018

More Implications of General Relativity A gravitational field may be “transformed away” at any point if we choose an appropriate accelerated frame of reference – a freely falling frame Einstein specified a certain quantity, the curvature of time-space, that describes the gravitational effect at every point 9/19/2018

Testing General Relativity General Relativity predicts that a light ray passing near the Sun should be deflected by the curved space-time created by the Sun’s mass The prediction was confirmed by astronomers during a total solar eclipse 9/19/2018

Black Holes If the concentration of mass becomes great enough, a black hole is believed to be formed In a black hole, the curvature of space-time is so great that, within a certain distance from its center, all light and matter become trapped 9/19/2018