Chapter 26. Relativity

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Chapter 26 Relativity

Time Dilation The vehicle is moving to the right with speed v A mirror is fixed to the ceiling of the vehicle An observer, O, at rest in this system holds a laser a distance d below the mirror The laser emits a pulse of light directed at the mirror (event 1) and the pulse arrives back after being reflected (event 2)

Time Dilation, Moving Observer Observer O carries a clock She uses it to measure the time between the events (Δt p ) The p stands for proper She observes the events to occur at the same place Δt p = distance/speed = (2d)/c

Time Dilation, Stationary Observer Observer O is a stationary observer on the earth He observes the mirror and O to move with speed v By the time the light from the laser reaches the mirror, the mirror has moved to the right The light must travel farther with respect to O than with respect to O

Time Dilation, Observations Both observers must measure the speed of the light to be c The light travels farther for O The time interval, Δt, for O is longer than the time interval for O, Δt p

Time Dilation, Time Comparisons Δt = where γ = Δt p 1 v 2 c 2 = γδt p 1 1 v 2 c 2 Observer O measures a longer time interval than observer O

Time Dilation, Summary The time interval Δt between two events measured by an observer moving with respect to a clock is longer than the time interval Δt p between the same two events measured by an observer at rest with respect to the clock A clock moving past an observer at speed v runs more slowly than an identical clock at rest with respect to the observer by a factor of γ -1

Identifying Proper Time The time interval Δt p is called the proper time The proper time is the time interval between events as measured by an observer who sees the events occur at the same position You must be able to correctly identify the observer who measures the proper time interval

Alternate Views The view of O that O is really the one moving with speed v to the left and O s clock is running more slowly is just as valid as O s view that O was moving The principle of relativity requires that the views of the two observers in uniform relative motion must be equally valid and capable of being checked experimentally

Time Dilation Generalization All physical processes slow down relative to a clock when those processes occur in a frame moving with respect to the clock These processes can be chemical and biological as well as physical Time dilation is a very real phenomena that has been verified by various experiments

Time Dilation Verification Muon Decays Muons are unstable particles that have the same charge as an electron, but a mass 207 times more than an electron Muons have a half-life of Δt p = 2.2µs when measured in a reference frame at rest with respect to them (a) Relative to an observer on earth, muons should have a lifetime of γ Δt p (b) A CERN experiment measured lifetimes in agreement with the predictions of relativity

The Twin Paradox The Situation A thought experiment involving a set of twins, Speedo and Goslo Speedo travels to Planet X, 20 light years from earth His ship travels at 0.95c After reaching planet X, he immediately returns to earth at the same speed When Speedo returns, he has aged 13 years, but Goslo has aged 42 years

The Twins Perspectives Goslo s perspective is that he was at rest while Speedo went on the journey Speedo thinks he was at rest and Goslo and the earth raced away from him on a 6.5 year journey and then headed back toward him for another 6.5 years The paradox which twin is the traveler and which is really older?

The Twin Paradox The Resolution Relativity applies to reference frames moving at uniform speeds The trip in this thought experiment is not symmetrical since Speedo must experience a series of accelerations during the journey Therefore, Goslo can apply the time dilation formula with a proper time of 42 years This gives a time for Speedo of 13 years and this agrees with the earlier result There is no true paradox since Speedo is not in an inertial frame

Length Contraction The measured distance between two points depends on the frame of reference of the observer The proper length, L p, 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

Length Contraction Equation L = L p γ = L p 1 v 2 c 2 Length contraction takes place only along the direction of motion

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

Relativistic Momentum To account for conservation of momentum in all inertial frames, the definition must be modified p mv 1 v 2 c 2 = γmv 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

Relativistic Energy The definition of kinetic energy requires modification in relativistic mechanics KE = γmc 2 mc 2 The term mc 2 is called the rest energy of the object and is independent of its speed The term γmc 2 is the total energy, E, of the object and depends on its speed and its rest energy

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 mass The mass of a particle may be completely convertible to energy and pure energy may be converted to particles

Energy and Relativistic Momentum It is useful to have an expression relating total energy, E, to the relativistic momentum, p E 2 = p 2 c 2 + (mc 2 ) 2 When the particle is at rest, p = 0 and E = E R = mc 2 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 = 931.494 MeV/c 2

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

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

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 spacetime, that describes the gravitational effect at every point

Curvature of Spacetime There is no such thing as a gravitational force According to Einstein Instead, the presence of a mass causes a curvature of spacetime in the vicinity of the mass This curvature dictates the path that all freely moving objects must follow

General Relativity Summary Mass one tells spacetime how to curve; curved spacetime tells mass two how to move John Wheeler s summary, 1979 The equation of general relativity is roughly a proportion: Average curvature of spacetime α energy density

Testing General Relativity General Relativity predicts that a light ray passing near the Sun should be deflected by the curved spacetime created by the Sun s mass The prediction was confirmed by astronomers during a total solar eclipse

Other Verifications of General Relativity Explanation of Mercury s orbit Explained the discrepancy between observation and Newton s theory The difference was about 43 arc seconds per century

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

Black Holes, cont The radius is called the Schwarzschild radius Also called the event horizon It would be about 3 km for a star the size of our Sun At the center of the black hole is a singularity It is a point of infinite density and curvature where spacetime comes to an end

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