28.6 Relativistic energy (Page 4/12)

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Kinetic energy and the ultimate speed limit

Kinetic energy is energy of motion. Classically, kinetic energy has the familiar expression $\frac{1}{2} {mv}^{2}$ . The relativistic expression for kinetic energy is obtained from the work-energy theorem. This theorem states that the net work on a system goes into kinetic energy. If our system starts from rest, then the work-energy theorem is

W_{net} = KE .

Relativistically, at rest we have rest energy $E_{0} = {mc}^{2}$ . The work increases this to the total energy $E = {γmc}^{2}$ . Thus,

W_{net} = E - E_{0} = γ {mc}^{2} - {mc}^{2} = (γ - 1) {mc}^{2} .

Relativistically, we have $W_{net} = {KE}_{rel}$ .

Relativistic kinetic energy

Relativistic kinetic energy is

{KE}_{rel} = (γ - 1) {mc}^{2} .

When motionless, we have $v = 0$ and

γ = \frac{1}{\sqrt{1 - \frac{v^{2}}{c^{2}}}} = 1,

so that ${KE}_{rel} = 0$ at rest, as expected. But the expression for relativistic kinetic energy (such as total energy and rest energy) does not look much like the classical $\frac{1}{2} {mv}^{2}$ . To show that the classical expression for kinetic energy is obtained at low velocities, we note that the binomial expansion for $γ$ at low velocities gives

γ = 1 + \frac{1}{2} \frac{v^{2}}{c^{2}} .

A binomial expansion is a way of expressing an algebraic quantity as a sum of an infinite series of terms. In some cases, as in the limit of small velocity here, most terms are very small. Thus the expression derived for $γ$ here is not exact, but it is a very accurate approximation. Thus, at low velocities,

γ - 1 = \frac{1}{2} \frac{v^{2}}{c^{2}} .

Entering this into the expression for relativistic kinetic energy gives

{KE}_{rel} = [\frac{1}{2} \frac{v^{2}}{c^{2}}] {mc}^{2} = \frac{1}{2} {mv}^{2} = {KE}_{class} .

So, in fact, relativistic kinetic energy does become the same as classical kinetic energy when $v << c$ .

It is even more interesting to investigate what happens to kinetic energy when the velocity of an object approaches the speed of light. We know that $γ$ becomes infinite as $v$ approaches $c$ , so that KE _rel also becomes infinite as the velocity approaches the speed of light. (See [link] .) An infinite amount of work (and, hence, an infinite amount of energy input) is required to accelerate a mass to the speed of light.

The speed of light

No object with mass can attain the speed of light.

So the speed of light is the ultimate speed limit for any particle having mass. All of this is consistent with the fact that velocities less than $c$ always add to less than $c$ . Both the relativistic form for kinetic energy and the ultimate speed limit being $c$ have been confirmed in detail in numerous experiments. No matter how much energy is put into accelerating a mass, its velocity can only approach—not reach—the speed of light.

In this figure a graph is shown on a coordinate system of axes. The x-axis is labeled as speed v (m/s). On the x-axis, velocity of the object is shown in terms of the speed of light starting from zero at origin to c, where c is the speed of light. The y-axis is labeled as Kinetic Energy K E (J). On the y-axis, relativistic kinetic energy is shown starting from 0 at origin to 1.0. The graph K sub r e l of relativistic kinetic energy is concave up and moving upward along the vertical line at x equals c. This graph shows that relativistic kinetic energy approaches infinity as the velocity of an object approaches the speed of light. Also shown is that when the speed of the object is equal to the speed of light c the kinetic energy is known as classical kinetic energy, which is denoted as K E sub class. — This graph of ${KE}_{rel}$ versus velocity shows how kinetic energy approaches infinity as velocity approaches the speed of light. It is thus not possible for an object having mass to reach the speed of light. Also shown is ${KE}_{class}$ , the classical kinetic energy, which is similar to relativistic kinetic energy at low velocities. Note that much more energy is required to reach high velocities than predicted classically.

Comparing kinetic energy: relativistic energy versus classical kinetic energy

An electron has a velocity $v = 0 . 990 c$ . (a) Calculate the kinetic energy in MeV of the electron. (b) Compare this with the classical value for kinetic energy at this velocity. (The mass of an electron is $9 . 11 \times 10^{- 31} kg$ .)

Questions & Answers

A golfer on a fairway is 70 m away from the green, which sits below the level of the fairway by 20 m. If the golfer hits the ball at an angle of 40° with an initial speed of 20 m/s, how close to the green does she come?

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2. A sled plus passenger with total mass 50 kg is pulled 20 m across the snow (0.20) at constant velocity by a force directed 25° above the horizontal. Calculate (a) the work of the applied force, (b) the work of friction, and (c) the total work.

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you have been hired as an espert witness in a court case involving an automobile accident. the accident involved car A of mass 1500kg which crashed into stationary car B of mass 1100kg. the driver of car A applied his brakes 15 m before he skidded and crashed into car B. after the collision, car A s

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can someone explain to me, an ignorant high school student, why the trend of the graph doesn't follow the fact that the higher frequency a sound wave is, the more power it is, hence, making me think the phons output would follow this general trend?

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Nevermind i just realied that the graph is the phons output for a person with normal hearing and not just the phons output of the sound waves power, I should read the entire thing next time

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Follow up question, does anyone know where I can find a graph that accuretly depicts the actual relative "power" output of sound over its frequency instead of just humans hearing

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"Generation of electrical energy from sound energy | IEEE Conference Publication | IEEE Xplore" ***ieeexplore.ieee.org/document/7150687?reload=true

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progressive wave

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A string is 3.00 m long with a mass of 5.00 g. The string is held taut with a tension of 500.00 N applied to the string. A pulse is sent down the string. How long does it take the pulse to travel the 3.00 m of the string?

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Source: OpenStax, College physics for ap® courses. OpenStax CNX. Nov 04, 2016 Download for free at https://legacy.cnx.org/content/col11844/1.14

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