The discussion revolves around the relationship between mass, energy, and temperature, particularly whether heating an object increases its weight. Participants explore concepts from modern relativity, the definition of mass, and the implications of energy changes on mass.
Participants express differing views on the relationship between mass and energy, particularly regarding whether heating an object affects its mass. There is no consensus on the implications of energy changes on mass or weight.
Discussions include references to historical paradigms and modern definitions of mass, highlighting the complexity of the topic and the need for careful consideration of definitions and assumptions.
Originally posted by loop quantum gravity
with the increase of a body's velocity to the speed of light (v->c) so does the body's mass increase m->infinity.
does this means that light has infinite mass? i know that light doesn't have rest mass because it never rests .
hope that my layman terms won't affect the answer.
Originally posted by loop quantum gravity
i was under the impression that when you acclerate a matter up to the speed of light the mass of the body increases, thanks for correcting me.
so the mass of a body stays constant all the time? (i derived that from ivariant- doesn't change).Originally posted by DW
Thats an old paradigm introduced by Tolman, Lewis, and Plank, not Einstein who came to oppose it, that has no place in modern relativity. The modern definition of mass is such that it does not depend on speed. It is invariant.
Originally posted by loop quantum gravity
so the mass of a body stays constant all the time? (i derived that from ivariant- doesn't change).
Originally posted by DW
Invariant and conserved mean two different things. An invariant thing does not change value with respect to velocity changes or in general in coordinate transformations. A conserved thing keeps the same value over time. The mass of an object is defined as its center of momentum frame energy divided by the square of the speed c. You can change the mass of an object over time simply by adding energy too it. Of course if you include the matter where that energy came from as a part of the system center of momentum frame energy and therefor mass will be conserved so whether the objects mass is conserved over time really depends on what you want to include as a part of the system defining the object.
By adding energy I do mean center of momentum frame energy. So, yes heating it up adds a minute amount of mass. Cooling it down subtracts mass from it. You may also remove mass simply by cutting a chunk off. It may also absord or emit latent energy in a phase change. You might also change the pressure at constant temperature.Originally posted by loop quantum gravity
"You can change the mass of an object over time simply by adding energy too it." -two questions: 1. the adding of energy will it increase the mass or decrease it? 2. the other way around of is substracting from the object energy and you can do so by freazing it then object looses energy but it doesn't affect the mass (so this is a bad example of substracting mass that will change the mass) can you give example of substraction of energy from object and as a consequence a change in the mass?