If you understand algebra then that's all you'll need. I placed the definitions and derivations on a web page. See - http://www.geocities.com/physics_world/sr/inertial_mass.htmMr. Tambourine Man said:OK, I'll admit...I am only a beginner, if even. I understand why time and length are effected by speed. But I've never understood why mass increases. Would someone kindly show me how and why mass increases the faster an object goes (using mathematical language understandable by someone who has not gone further than calculus)? Thank you.
Mr. Tambourine Man said:OK, I'll admit...I am only a beginner, if even. I understand why time and length are effected by speed. But I've never understood why mass increases. Would someone kindly show me how and why mass increases the faster an object goes (using mathematical language understandable by someone who has not gone further than calculus)? Thank you.
That is the more popular convention. It is not exclusively true in all cases. Texts such as that by Rindler, Mould, d'Inverno, Misner, Thorne and Wheeler, and Peacock use mass in most places to mean "relativistic mass."Garth said:Whether you want to call such "relativistic mass" or not is a matter of convention, the standard convention is to leave the term 'mass' for only the rest mass of an object.
Garth
pmb_phy said:That is the more popular convention. It is not exclusively true in all cases. Texts such as that by Rindler, Mould, d'Inverno, Misner, Thorne and Wheeler, and Peacock use mass in most places to mean "relativistic mass."
Pete
how? should our message contain? at its end?daniel_i_l said:It is possible to measure inertial mass with a clock and ruler, if they give different measurements then the mass will be measured differently to.
bernhard.rothenstein said:how?
It depends on what the object is whose mass you wish to measure. E.g. if its charged particle of charge q then we can launch it into a uniform magnetic field, of strenght B, in a direction which is perpendicular to the field lines. The charged particle will move in a cirlce of radiius r. As shown heredaniel_i_l said:It is possible to measure inertial mass with a clock and ruler, if they give different measurements then the mass will be measured differently to.
According to Einstein's theory of relativity, mass and energy are equivalent and can convert into one another. As an object moves faster, its kinetic energy increases, causing its mass to also increase. This is known as mass-energy equivalence.
In a chemical reaction, the total mass of the reactants is always equal to the total mass of the products. However, the individual masses of the reactants and products may be different due to changes in the arrangement of atoms and the formation of new chemical bonds.
No, an object's mass does not increase with temperature. The increase in size or volume of an object due to temperature changes is a result of thermal expansion, but the mass remains the same.
Mass increases in a gravitational field because of the gravitational force acting on the object. According to Newton's law of gravitation, the force of attraction between two objects is directly proportional to their masses. Therefore, the more massive an object is, the greater its gravitational force, resulting in an increase in its weight.
In nuclear reactions, mass can increase or decrease due to the conversion of mass into energy or vice versa. This is described by the famous equation E=mc², where E represents energy, m represents mass, and c represents the speed of light. During nuclear fusion reactions, the total mass of the reactants is greater than the total mass of the products, and the difference is released as energy.