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Derivation of Einstein`s Energy Equation from Maxwell`s Electric
... a purely kinematical effect. Hence, according to Einstein the relativistic mass is not a physical effect but rather the result of the effect of relative motion on observation. Einstein then derives his equation mathematically and under special conditions, which requires the above speculation. Theref ...
... a purely kinematical effect. Hence, according to Einstein the relativistic mass is not a physical effect but rather the result of the effect of relative motion on observation. Einstein then derives his equation mathematically and under special conditions, which requires the above speculation. Theref ...
Part II. Statistical mechanics Chapter 9. Classical and quantum
... Chapter 9. Classical and quantum dynamics of density matrices Statistical mechanics makes the connection between macroscopic dynamics and equilibriums states based on microscopic dynamics. For example, while thermodynamics can manipulate equations of state and fundamental relations, it cannot be use ...
... Chapter 9. Classical and quantum dynamics of density matrices Statistical mechanics makes the connection between macroscopic dynamics and equilibriums states based on microscopic dynamics. For example, while thermodynamics can manipulate equations of state and fundamental relations, it cannot be use ...
Document
... entire band has to be included in external space X – collective coordinate(s) conjugate to violated P ...
... entire band has to be included in external space X – collective coordinate(s) conjugate to violated P ...
Document
... Two possible interpretations (1) A particle moves forward in time, emits two photons at ( x2 , t2 ) and moves back in time with negative energy to point ( x1 , t1 ) where it scatters off a photon and moves forward in time. There is only one particle moving through space and time. (2) At point ( x1 , ...
... Two possible interpretations (1) A particle moves forward in time, emits two photons at ( x2 , t2 ) and moves back in time with negative energy to point ( x1 , t1 ) where it scatters off a photon and moves forward in time. There is only one particle moving through space and time. (2) At point ( x1 , ...