Why Does Density Increase When an Object Moves By?

In summary, the density of an object increases as it moves by an observer due to Lorentz contraction and the transformation of energy between frames. This results in a higher density in the observer's frame compared to the rest frame. The increase in density can be quantified by the formula rho' = rho/(1 - v^2 / c^2), where v is the velocity of the object and c is the speed of light. This is due to the two factors of gamma, representing the Lorentz contraction and energy transformation, in the stress-energy tensor.
  • #1
jgens
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When an object moves by you, I know that its density is supposed to increase (at least that's what I was told by my physics teacher); however, I don't understand why. I understand why the density is greater in a moving reference frame relative to an observer at rest, but why does it continue to increase as it moves by you?

Thanks.
 
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  • #2
Your physics teacher is probably thinking that if a box of mass M and dimension x by y by z traveling in the z direction has its z dimension reduced by the Lorentz contraction. So the volume of the box has apparently shrunk. But mass is conserved.
 
  • #3
I don't quite follow. I understand that the observer at rest would see the length of the box contract in its direction of motion, and that, assuming work was done on the box, the mass of the box appears to increase as well. However, I do not understand how the density continues to increase as the box approaches the observer.
 
  • #4
If it approaches inertially then the density will be constant (but higher than the density in the rest frame).
 
  • #5
That's what I thought. Perhaps that's what my teacher meant by density increasing as the block passes by you. Thanks.
 
  • #6
As others have said, the mass-energy density rho' in the observer's frame is constant (if velocity is constant) and greater than the density rho as measured in a frame in which the stuff is at rest.

For completeness, I'll make things a bit quantitative, even though jgens does not need an answer at this level.

The two densities differ by two factors of gamma = 1/sqrt(1 - V^2 / c^2), roughly, one for Lorentz contraction and one for the transformation of energy between the two frames. Consequently,

rho' = rho/(1 - v^2 / c^2).

A more sophisticated way to look at it is that density is the zero-zero component of the stress-energy tensor, and there is a factor of gamma for each of the two indices.
 

Related to Why Does Density Increase When an Object Moves By?

1. Why does density increase when an object moves by?

Density is defined as the mass per unit volume of a substance. When an object moves, it experiences a change in velocity, which results in a change in its kinetic energy. This increase in kinetic energy causes the particles within the object to move faster and spread out, increasing the volume of the object. However, the mass of the object stays the same. As a result, the mass per unit volume, which is the definition of density, increases.

2. Does density always increase when an object moves by?

No, density does not always increase when an object moves by. It depends on the type of object and the conditions in which it is moving. For example, if an object is moving through a fluid, the density of the fluid may impact the density of the object. Additionally, if the object is compressed or expands while moving, its density may change as well.

3. Is the density of an object the same in all reference frames?

No, the density of an object can vary in different reference frames. This is because the density of an object is dependent on its mass and volume, both of which can be affected by the reference frame in which it is measured. For example, if an object is moving at a high velocity, its mass may appear to increase due to relativistic effects, resulting in a change in its density.

4. How does the density of an object affect its buoyancy?

The density of an object plays a crucial role in its buoyancy. According to Archimedes' principle, an object will float in a fluid if its density is less than that of the fluid, and it will sink if its density is greater. This is because the denser object will displace more fluid and experience a greater upward force, making it more buoyant. Therefore, as an object's density increases, its buoyancy also increases.

5. Can an object's density change without changing its mass or volume?

Yes, an object's density can change without changing its mass or volume. This can occur if the temperature or pressure of the object changes. For example, when a gas is compressed, its particles are pushed closer together, resulting in an increase in density. However, the mass and volume of the gas remain the same. Similarly, when a substance undergoes a phase change, such as from a liquid to a solid, its density can also change without a change in mass or volume.

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