The Particle as a Statistical Ensemble of Events in Stueckelberg–Horwitz–Piron Electrodynamics

Land, Martin

doi:10.3390/e19050234

Cited by 5 publications

(11 citation statements)

References 21 publications

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“…The energy that is being achieved by modern accelerators is making it possible to study the behavior of matter during the earliest, and hottest, moments of the big bang. Parametrized electrodynamics [26,27] may need to be extended to study matter in a plasma state.…”

Section: Discussionmentioning

confidence: 99%

Comparative Analysis of Jüttner’s Calculation of the Energy of a Relativistic Ideal Gas and Implications for Accelerator Physics and Cosmology

Fanchi

2017

Entropy

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Jüttner used the conventional theory of relativistic statistical mechanics to calculate the energy of a relativistic ideal gas in 1911. An alternative derivation of the energy of a relativistic ideal gas was published by Horwitz, Schieve and Piron in 1981 within the context of parametrized relativistic statistical mechanics. The resulting energy in the ultrarelativistic regime differs from Jüttner's result. We review the derivations of energy and identify physical regimes for testing the validity of the two theories in accelerator physics and cosmology.

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Section: Discussionmentioning

confidence: 99%

Comparative Analysis of Jüttner’s Calculation of the Energy of a Relativistic Ideal Gas and Implications for Accelerator Physics and Cosmology

Fanchi

2017

Entropy

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“…An event e k and the corresponding temporal update n − 1 → n is always associated with the change of the state of an object O according to (14). Its state S OO (n) just after the event corresponds to the present state of the object at time n. We may also have memories at time n of its preceding state S OO (n − 1).…”

Section: Sequential and Relational Timementioning

confidence: 99%

“…Several researchers have developed Stueckelberg's formalism further [10][11][12][13][14]. However, there is still no generally accepted physical motivation for the introduction of the additional evolution parameter λ .…”

Section: Introductionmentioning

confidence: 99%

“…The parameter λ is commonly related to the proper time along the world line of a given particle [11,16]. Some researchers try to generalize this notion so that the same invariant λ can describe the evolution of many particles, making it similar to the external, absolute time of Newtonian mechanics [12][13][14]17]. Some authors argue that it is possible to construct a clock that measures the value of λ [16], whereas others argue that λ is not observable [17].…”

Section: Introductionmentioning

confidence: 99%

“…In so doing we are able to get a new perspective on the Dirac equation and the operators that are associated with observables in quantum mechanics. The parameter σ plays a similar role in the present formalism as the parameter λ in Stueckelberg's theory [8][9][10][11][12][13][14][15][16][17].…”

Section: Introductionmentioning

confidence: 99%

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Evolution equations from an epistemic treatment of time

Östborn

2018

Preprint

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Relativistically, time t may be seen as an observable, just like position r. In quantum theory, t is a parameter, in contrast to the observable r. This discrepancy suggests that there exists a more elaborate formalization of time, which encapsulates both perspectives. Such a formalization is proposed in this paper. The evolution is described in terms of sequential time n ∈ N, which is updated each time an event occurs. Sequential time n is separated from relational time t, which describes distances between events in space-time. There is a space-time associated with each n, in which t represents the knowledge at time n about temporal relations. The evolution of the wave function is described in terms of the parameter σ that interpolates between sequential times n. For a free object we obtain a Stueckelberg equation d dσ Ψ(r 4 , σ ) = ic 2 h 2 ε ✷Ψ(r 4 , σ ), where r 4 = (r, ict). Here σ describes the time m passed from the start of the experiment at time n and the observation at time n + m. The parametrization is assumed to be natural in the sense that d dσ t = 1, where t is the expected temporal distance between the events that define n and n + m. The squared rest energy ε 2 0 is proportional to the eigenvalue σ that describes a stationary state Ψ(r 4 , σ ) = ψ(r 4 , σ )e i σ σ . The Dirac equation follows as a square root of the stationary state equation from the condition σ > 0, which is a consequence of the directed nature of n. The formalism thus implies that all observable objects have non-zero rest mass, including elementary fermions. The introduction of n releases t, so that it can be treated as an observable with uncertainty ∆t.

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Classical Electrodynamics

Land

Horwitz

2020

Relativistic Classical Mechanics and Electrodynamics

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The Particle as a Statistical Ensemble of Events in Stueckelberg–Horwitz–Piron Electrodynamics

Cited by 5 publications

References 21 publications

Comparative Analysis of Jüttner’s Calculation of the Energy of a Relativistic Ideal Gas and Implications for Accelerator Physics and Cosmology

Comparative Analysis of Jüttner’s Calculation of the Energy of a Relativistic Ideal Gas and Implications for Accelerator Physics and Cosmology

Evolution equations from an epistemic treatment of time

Classical Electrodynamics

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