# Why does the mass of an object increase when its speed approaches that of light?

I'm reading Nano: The Essentials by T. Pradeep and I came upon this statement in the section explaining the basics of scanning electron microscopy.

However, the equation breaks down when the electron velocity approaches the speed of light as mass increases. At such velocities, one needs to do relativistic correction to the mass so that it becomes...

We all know about the famous theory of relativity, but I couldn't quite grasp the "why" of its concepts yet. This might shed new light on what I already know about time slowing down for me if I move faster.

Why does the mass of an object increase when its speed approaches that of light?

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Mass doesn't change, it's an invariant! – user12345 May 8 at 18:16

The complete relevant text in the book is

The de Broglie wave equation relates the velocity of the electron with its wavelength, λ = h/mv ... However, the equation breaks down when the electron velocity approaches the speed of light as mass increases. ...

Actually, the de Broglie wavelength should be $$\lambda = \frac hp,$$ where p is the momentum. While p = mv in classical mechanics, in special relativity the actual relation is $$\mathbf p = \gamma m \mathbf v = \frac{m\mathbf v}{\sqrt{1-\frac{v^2}{c^2}}}$$ where m is the rest mass. If we still need to make the equation p = mv correct, we introduce the concept of "relativistic mass" M = γm which increases with v.

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Does it answer the 'Why'? – LifeH2O Dec 24 '10 at 13:18
A good "why" is given here: physics.stackexchange.com/a/43982/4552 – Ben Crowell May 8 at 23:23

The mass (the true mass which physicists actually deal with when they calculate something concerning relativistic particles) does not change with velocity. The mass (the true mass!) is an intrinsic property of a body, and it does not depends on the observer's frame of reference. I strongly suggest to read this popular article by Lev Okun, where he calls the concept of relativistic mass a "pedagogical virus".

What actually changes at relativistic speeds is the dynamical law that relates momentum and energy depend with the velocity (which was already written). Let me put it this way: trying to ascribe the modification of the dynamical law to a changing mass is the same as trying to explain non-Euclidean geometry by redefining $\pi$!

Why this law changes is the correct question, and it is discussed in the answers here.

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Nice analogy ;-) – David Zaslavsky Dec 11 '10 at 0:37
This is the correct answer. – Killercam May 8 at 17:38
@Killercam, yep. +1 for Okun – Peter Kravchuk May 8 at 20:41
This doesn't answer the question. It just advises the OP to ask the question in different language. – Ben Crowell May 8 at 23:18

If you want to intuitively see why the mass increases, consider the following.

• Firstly, nothing can travel faster than the speed of light (this is the premise on which Special Relativity is based)

• Secondly, applying a force to an object will increase its kinetic energy (assuming the force acts in the same direction as the object's motion)

Since kinetic energy $K.E.$ = $0.5 * m * v^2$, if $v$ is limited to $c$, then as $v$ approaches $c$ the only way for $K.E.$ to increase is for $m$ to increase.

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I have never before heard that special relativity is based on the premise that nothing can move faster than light. Elementary SR usually says 1) The speed of light is constant in all frames. 2) All physical laws are the same in inertial frames. – Mark Eichenlaub Dec 6 '10 at 20:58
@Mark: correct. SR says no such thing and actually admits existence of tachyons. The sectors "faster than light" and "slower than light" are obviously dual to each other and SR doesn't distinguish between them at all. The reason why we don't want tachyons is an additionally assumption of causality. – Marek Dec 6 '10 at 21:11
+1 @Sam, I was also thinking along the same line you did, relating mass to speed and energy. – Kit Dec 7 '10 at 0:10
This argument is wrong. Relativistic kinetic energy doesn't equal $(1/2)mv^2$, and doesn't approach a limit as $v$ approaches $c$. – Ben Crowell May 8 at 23:14

There is a point of view, that under the term "the mass" one must mean "the rest mass".

From that point of view there is obviously no dependence of the (rest) mass on the speed of an object. And, therefore, the mass of an object does not increase when its speed increases.

The correct (from that point of view) way to talk about the fenomenon is to say that with increase of the speed of an object you need more and more energy in order to make it move faster.

Of cource there is no fundamental controversy between thsi point of view and that of many books and articles. But the usage of the concept of "realtivistic mass" makes things much more complicated, even if it was introduced in pursuit of simplicity.

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The phenomenon you are talking about (one in the italics) is actually quite similar to definition of inertial mass. Inertial mass measures how hard it is to move an object. And this is why the concept of relativistic mass is useful. It is similar to inertial mass. On the other hand, invariant mass is just a number that characterizes the particle but has nothing to do with dynamics. I think properly distinguishing between various concepts of masses takes some time and thinking (and there is also gravitational mass and related equivalence principle but let's leave that for another time). – Marek Dec 6 '10 at 18:02
Inertial mass measures how hard it is to move an object. Yes. But note that you can change the speed of an object in different directions. Do deal with that you will need to introduce "logitudinal" and "transverse inertial masses". I support people, saying that talking about "inertial mass" is an overcomplication leading to mistakes and "terminological swamp". – Kostya Dec 6 '10 at 18:24
Point taken Kostya. These past few days I've been shown quite a huge heap of evidence that any concept of mass different from invariant mass is really too messy to be worth even talking about :-) And I really have to wonder why I was introduced to all these things when I was learning SR myself (from books and also at our uni SR course). They seem just an unnecessary baggage now. But perhaps it is still useful to know these concepts exist? I am not sure. – Marek Dec 6 '10 at 19:57
I had the same confusion about this unecessary baggage after I dscovered all this mess. The person, who promotes the "only rest mass" point of view is Lev Okun. The great, very basic and free book on that topic: "ENERGY AND MASS IN RELATIVITY THEORY" by Lev B Okun – Kostya Dec 7 '10 at 9:45

Fundamentally, mass and energy are the same thing. They are two "points of view" of the same reality.

From the "point of view" (inertial frame) of an electron, its mass does not increase, its speed is always zero.

From the "point of view" (inertial frame) of a stationary observer, the electron has a very high kinetic energy (some in the mass term and some in the speed term)

From the "point of view" (inertial frame) of a moving observer, the electron has a different kinetic energy (some in the mass term and some in the speed term)

And so on.

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Keeping it simple (with a link):

Special Relativity

"The relativistic increase of mass happens in a way that makes it impossible to accelerate an object to light speed: The faster the object already is, the more difficult any further acceleration becomes. The closer the object's speed is to light speed, the greater the increase in inertial mass; to reach light speed exactly would require an infinitely strong force acting on the body. This enforces special relativity's speed limit: No material object can be accelerated to light speed.

The increase in inertial mass is part of a more general phenomenon, the relativistic equivalence of mass and energy: If one adds energy to a body, one automatically increases its mass; if one takes energy away from it, one decreases its mass. In the case of acceleration, the object in question gains kinetic energy ("movement energy"), and this increase in energy automatically means an increase in mass."

This, to most, helps clear things up without adding complexity. You are, of course, welcome to delve deeper.

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In special relativity the actual invariant is the magnitude of the covariant energy momentum 4-vector (E/c, p_x,p_y,p_z), not the apparent mass itself. See also the section on "momentum in 4 Dimensions", here. The apparent mass in a moving frame is just a projection.

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The mass of object changes when its speed approaches zero because according to Einstein postulates of theory of relativity all the laws are same in all inertial frames and speed of light remains constant in inertial frame in vacuum. All the concepts of relativity are based on these two postulates. As one can not add any speed in speed of light, the Lorentz transformation equations are derived and using these variation of mass with velocity relation. Almost every concept of Physics changes at a speed comparative to speed of light.

One can see the derivation here

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I don't really think we really know "why", we only know that it does increase. The answer to the questions like "why the laws of nature are the way they are?" is beyond the scope of physics, it's a matter of philosophy.

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I have a strong urge to down-vote this answer. We know why some things are way they are assuming some (very few) basics principles. Of course, there are always some axioms we can't deduce but have to experimentally verify but all the rest of physics can be deduced from those axioms. So your answer is just a rant stating the obvious and not helping at all. – Marek Dec 6 '10 at 22:51