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A Sub-Quantum Theory: Theoretical and Experimental Proposal

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09 June 2026

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16 June 2026

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Abstract
For nearly a century, quantum mechanics (QM) has established itself as an exceptionally effective framework for predicting the collective movements and statistical distributions of particles. However, its predictive success comes with a significant conceptual cost: the apparent abandonment of local realism. When one attempts to apply the standard quantum formalism at the scale of an individual particle, paradoxes inevitably arise. This article argues that these contradictions are not intrinsic properties of nature, but rather stem from a fundamental category error: the misapplication of ensemble statistical laws to individual events, which unrightfully promotes statistical averages to instantaneous physical realities. To address the root cause of this conceptual deviation, we must establish a foundational axiom: the Principle of Particle Reality. This principle posits that if a particle exists as a real entity, it must inherently possess definite physical properties—such as a precise polarization, velocity, and trajectory—independent of our capacity to detect them. Ignoring this ontology has led the standard model to treat physical realities as abstract paradoxes. To resolve them, this work proposes a unified reconsideration of three main pillars of quantum interpretation. First, regarding locality, we demonstrate that the passage probabilities through two polarizers for a particle within an unpolarized beam remain identical regardless of their order. Governed by Malus's law and the strict mathematical symmetry \cos^2(a-b) = \cos^2(b-a), this establishes that polarizers can be arranged in any sequential order or even in parallel for statistically identical pairs without altering the total passage probabilities. By establishing a physical equivalence, we show that exact quantum correlations emerge directly from a particle-by-particle application of the strictly positive classical Malus's law (0 \le p \le 1). This successfully explains the violation of Bell’s inequalities within a strictly local framework, bypassing the non-physical negative quasi-probabilities encountered in previous angular hidden-variable models. Secondly, on the illusion of state superposition, we show that failing to recognize that an interferometer physically and deterministically alters the polarization orientation of a particle led to an abstract formulation; in reality, this involves a deterministic geometric transformation of probability distributions. Finally, addressing wave-particle duality, we challenge the standard postulate of artificial simultaneity in the double-slit configuration, which caused a deep confusion between the collective behavior of a group and the sequential passage of an individual entity. We introduce an ``event-by-event'' formulation where interference fringes emerge instead from temporal correlations preserved by the non-commutativity of averaging. By restoring the strict distinction between statistical ensemble laws and individual reality through the Principle of Particle Reality, this work aims to definitively end ``quantum geocentrism'' and to lay the foundations for a coherent, local, and realistic sub-quantum physics.
Keywords: 
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Conceptual Framework: Statistical Identity & Temporal Realism

Locality and Statistical Identity (Bell’s Theorem)

Our approach relies on the principle of Statistical Identity: "entangled" pairs are treated as particles emitted with an identical hidden variable (orientation) λ , such that λ 1 = λ 2 . Under this condition, we propose a fundamental equivalence:
The statistical outcome of two identical particles passing through two spatially separated polarizers ( P A and P B ) is indistinguishable from the outcome of a single particle passing through two successive polarizers ( P A then P B ).
In a standard sequential setup, the first polarizer P A acts as a selector: it filters the population based on the geometric compatibility of λ with P A . In the parallel Bell setup [4,8], the measurement at P A on Particle 1 performs this exact same selection. Since Particle 2 shares the identical orientation λ , the fact that Particle 1 passed P A reveals that Particle 2 inherently belongs to the subset of orientations compatible with P A . Consequently, when Particle 2 encounters P B , its probability of passage is governed by the relative angle θ A B , exactly as if it had physically passed through P A first.
Thus, the correlation in cos 2 ( θ A B ) is not the result of an instantaneous influence at a distance, but the direct application of Malus’s Law to a statistically identical doublet, preserving strict locality. The spatial separation of the particles does not break the logical chain of conditional probability established by their common origin.

Temporal Realism and the Simultaneity Postulate (Young’s Slits)

Standard quantum mechanics describes the field in a double-slit experiment using a single time variable t:
E 1 ( t ) = E 01 cos ( ω t + ϕ 1 )
Assuming that the field passes through both slits at the exact same time t is not an experimental result, but a **postulate of simultaneity**. This assumption inherently forces the emergence of interference terms. To avoid this petitio principii, we must treat the events realistically with distinct temporal variables:
E 1 ( t 1 ) = E 01 cos ( ω t 1 + ϕ 1 ) and E 2 ( t 2 ) = E 02 cos ( ω t 2 + ϕ 2 )
By introducing distinct times t 1 and t 2 , the time dependence does not automatically vanish upon averaging. The persistence of interference relies on the non-commutativity of temporal averaging over a product:
f ( t ) · g ( t ) f ( t ) · g ( t )
Consequently, the intensity I new takes a form that explicitly depends on the sum and difference of times.
The non-simplified form (sum of independent impacts):
I new ( x , t 1 , t 2 ) = I 1 ( x ) 1 + cos ( 2 ω t 1 + 2 ϕ 1 ( x ) ) + I 2 ( x ) 1 + cos ( 2 ω t 2 + 2 ϕ 2 ( x ) ) .
The simplified form (modulated product):
I new ( x , T sum , Δ t ) ( I 1 ( x ) + I 2 ( x ) ) 1 + cos ( ω T sum + ϕ sum ) cos ( ω Δ t + Δ ϕ ) .
The interference pattern is modulated by a temporal term involving T sum . This confirms that fringes are not static abstractions but dynamic structures stabilized by temporal correlations.
The disappearance of fringes over extremely long durations (drift) becomes a testable prediction of the finite temporal coherence of the source, rather than a theoretical flaw.

1. Reinterpreting Locality: Malus’s Law and Bell’s Inequalities

1.1. The Standard Quantum Postulate

Quantum physics interprets the violation of Bell’s inequalities [4,6] as the irrefutable proof of non-locality non-locality [2]. According to this view, the existence of a correlation stronger than what classical mechanics would allow implies that particles must “communicate” instantaneously (faster than the speed of light) or be “non-local states” to coordinate their measurement outcomes, even when separated by great distances.

1.2. The Locality Argument (Malus’s Law)

The argument is based on the fact that the standard interpretation ignored the full scope of local probabilistic laws, notably Malus’s Law, when applied to pairs of particles produced with an identical orientation (polarization). Experiments on Bell’s inequalities can be reinterpreted as only demonstrating the reality of Malus’s Law and that we can create identically oriented (polarized or anti-polarized) particles simultaneously, but without any long-distance interaction.
This perspective finds strong formal support in the work of K. Wódkiewicz [18], who demonstrated that the quantum Malus’s law shares the exact mathematical structure of a local hidden-variable theory. However, whereas Wódkiewicz is constrained to introduce negative quasi-probabilities to fit the standard formalism, our approach resolves this contradiction. By establishing a physical equivalence between parallel and sequential measurements via the Statistical Identity of doublets, it allows for the direct application of the strictly positive classical Malus’s law ( 0 p 1 ), reproducing the exact quantum correlations without any mathematical anomalies.

1.3. Experimental Scenario (4 Detectors: a 1 , b 1 and a 2 , b 2 )

Consider non-polarized source modeled by a uniform distribution ρ ( λ ) = 1 2 π , emitting two identical particles photons (identical responses to the same measurements but strictly local, without any distance-related influence) sent to two measurement arms. Photon 1 passes through a 1 then b 1 . Photon 2 passes through b 2 then a 2 . The polarizer angle a 1 = a 2 and the polarizer angle b 1 = b 2 throughout the experiment . We assume we remove detector a 2 and b 1 .
For Photon 1 (passing through a 1 then b 1 ), the local probabilities are:
  • Probability to pass a 1 :
    P ( a 1 + ) = 0 2 π cos 2 ( λ a 1 ) ρ ( λ ) d λ = 1 2
  • Probability to pass b 1 given that it passed a 1 (Malus’s Law):
    P ( b 1 + | a 1 + ) = cos 2 ( Δ θ b 1 , a 1 )
  • Joint probability to pass both (sequential a 1 then b 1 ):
    P ( a 1 + , b 1 + ) = P ( a 1 + ) × P ( b 1 + | a 1 + ) = 1 2 cos 2 ( Δ θ b 1 , a 1 )
  • Joint probability to pass a 1 but be blocked by b 1 :
P ( a 1 + , b 1 ) = P ( a 1 + ) × P ( b 1 | a 1 + ) = 1 2 sin 2 ( Δ θ b 1 , a 1 )
Note: We apply Malus’s law photon by photon to avoid confusion between global transmission probabilities and single-photon passage probabilities. The passage of a photon through a 1 and b 1 (in any sequence) thus reveals the pre-existing passage probabilities for its twin through b 2 and a 2 (also in any sequence), without any possibility to influence it.
For Photon 2 (passing through b 2 then a 2 ), the local probabilities are:
P ( b 2 + ) = 1 2 , P ( b 2 ) = 1 2 , P ( b 2 + | a 2 + ) = cos 2 ( Δ θ a 2 , b 2 ) , P ( b 2 + | a 2 ) = sin 2 ( Δ θ a 2 , b 2 )
P ( b 2 + , a 2 + ) = 1 2 cos 2 ( Δ θ a 2 , b 2 ) , P ( b 2 + , a 2 ) = 1 2 sin 2 ( Δ θ a 2 , b 2 )
Inter-Photon Correlation ( a 1 vs b 2 ): The calculation of the correlation E ( ` a 1 , ` b 2 ) depends only on the settings of the first detector of Photon 1 ( a 1 ) and the first detector of Photon 2 ( b 2 ), and the identical nature of their initial state λ . We have the trigonometric identities:
cos 2 ( θ b 2 θ a 2 ) = cos 2 ( θ a 2 θ b 2 ) , sin 2 ( θ b 2 θ a 2 ) = sin 2 ( θ a 2 θ b 2 ) .
Numerically, the probability values are therefore the same regardless of polarizer order ( a 1 = a 2 , b 1 = b 2 ) :
P ( a 1 + , b 1 + ) = P ( a 1 + , b 2 + ) = P ( b 2 + , a 2 + ) = P ( b 2 + , a 1 + ) = 1 2 cos 2 ( Δ θ ) and
P ( a 1 + , b 1 ) = P ( a 1 + , b 2 ) = P ( b 2 + , a 2 ) = P ( b 2 + , a 1 ) = 1 2 sin 2 ( Δ θ ) .
so we have : P ( a 1 + , b 2 ) = P ( a 2 + , b 2 ) = P ( b 2 , a 2 + ) = 1 2 sin 2 ( Δ θ ) , a n d P ( b 2 ) = 1 / 2 ,   s o P ( b 2 , a 2 ) = 1 2 cos 2 ( Δ θ )
Thus, we have the equalities for identical particles:
P ( a 1 + , b 2 + ) = P ( a 1 , b 2 ) = 1 2 cos 2 ( Δ θ ) P ( a 1 + , b 2 ) = P ( a 1 , b 2 + ) = 1 2 sin 2 ( Δ θ )
Correlation Calculation:
E ( θ a 1 , θ b 2 ) = p ( + + ) + p ( ) p ( + ) p ( + )
= 1 2 cos 2 Δ θ + 1 2 cos 2 Δ θ 1 2 sin 2 Δ θ + 1 2 sin 2 Δ θ = cos 2 Δ θ sin 2 Δ θ
E ( θ a 1 , θ b 2 ) = cos ( 2 Δ θ )
With the standard CHSH combination: S = E ( a , b ) + E ( a , b ) + E ( a , b ) E ( a , b )
and the angles a = 0 , a = π 4 , b = π 8 , b = 7 π 8 : | S | = 2 2 > 2
Removing the two duplicate polarizers from b 1 and a 2 that are behind the first polarizers in the paths will not create non-locality, and it will preserve realism and setting independence, while preserving the same probability of Bell’s violation. This observation fundamentally calls into question all interpretations that Bell’s violations could have proven, such as entanglement (non-locality) or non-realism.
Conclusion: any system with a single particle or twin particles with statistical identity satisfying perfect marginal equilibrium must inevitably lead to CHSH violations.

1.4. Statistical Identity

Our theoretical framework unifies quantum phenomena under the principle of statistical identity, with profound implications for understanding EPR correlations:
- Bell violations prove statistical identity, not non-locality (Entanglement).
- Quantum correlations emerge from classical geometric constraints.
Statistical identity means that two particles share exactly the same probabilistic properties, without any influence at a distance:
- Same probability distribution ρ ( λ ) - Same response A ( θ , λ ) to any measurement θ - Same realization of λ for each pair
ρ 1 ( λ ) = ρ 2 ( λ ) = ρ ( λ ) , A ( 1 ) ( θ , λ ) = A ( 2 ) ( θ , λ ) = A ( θ , λ )
Emissions possibility: Unpolarized emitters ( P ( A + ) = P ( B + ) = 0.5 ):
  • Random behavior: (null correlations)
  • Correlated behavior: P ( + + ) = P ( ) = 1 2 cos 2 ( Δ θ ) , P ( + ) = P ( + ) = 1 2 sin 2 ( Δ θ ) (correlations cos ( 2 Δ θ ) )
  • Anti-correlated behavior: P ( + ) = P ( + ) = 1 2 cos 2 ( Δ θ ) , P ( + + ) = P ( ) = 1 2 sin 2 ( Δ θ ) (correlations cos ( 2 Δ θ ) )
This result shows that quantum physics predictions are perfectly consistent with locality. If this reinterpretation of Malus’s Law is adopted. Particles do not need to communicate at any distance.

2. Reinterpreting of Superposition: The Interferometer Experiment

2.1. The Standard Quantum Postulate

Standard quantum mechanics interprets the operation of an interferometer (Mach-Zehnder type) by the principle of state superposition. It postulates that a particle entering the device simultaneously places itself in two distinct states (or paths) (e.g., | ψ = 1 2 ( | 0 + | 1 ) ). The interference fringes at the output are said to result from the interaction of these two superimposed realities when they recombine (the famous "collapse").

2.2. The Realistic Argument (Geometric Transformation)

The realistic approach demonstrates that the interferometer is not a creator of ontological superpositions, but a device performing a geometric rotation of the polarization (or phase) angle, simply transforming the probabilistic distributions according to Malus’s Law.

2.3. Probabilistic Transformation by Geometric Rotation

Consider a polarized source at angle λ 0 and a detector oriented at angle a and x = λ 0 a . According to Malus’ law:
P ( a + ) = cos 2 ( λ 0 a ) = cos 2 ( x ) and P ( a ) = sin 2 ( λ 0 a ) = sin 2 ( x )

2.4. Deterministic and Balanced States

The analysis of angles reveals distinct regimes:
  • Deterministic States ( x = k π ):  P ( a + ) = 1 , P ( a ) = 0 . Maximum tendency toward positive detection.
  • Opposite States ( x = ( 2 k + 1 ) π / 2 ):  P ( a ) = 1 , P ( a + ) = 0 . Maximum tendency toward negative detection.
  • Balanced States ( x = ( 2 k + 1 ) π / 4 ):  P ( a + ) = P ( a ) = 1 / 2 . Equal probabilities between both tendencies.
Intermediate states exhibit a probabilistic advantage ( P ( + ) > P ( ) or P ( ) > P ( + ) ) without absolute determinism.

2.5. The Interferometer Mechanism

The interferometer physically performs a π / 4 rotation on the angle λ 0 , transforming probabilistic distributions:
  • Transformation from Extreme States to Balanced Marginals:
    Positive state ( x = k π ) π / 4 x = ( 2 k + 1 ) π / 4 P ( + ) = P ( ) = 1 / 2
    Negative state ( x = ( 2 k + 1 ) π / 2 ) π / 4 x = ( 2 k + 1 ) π / 4 P ( + ) = P ( ) = 1 / 2
  • Transformation from Balanced Marginals to Extreme States:
    Balanced ( x = ( 2 k + 1 ) π / 4 ) + π / 4 x = k π Output + ( Constructive )
    Balanced ( x = ( 2 k + 1 ) π / 4 ) π / 4 x = ( 2 k + 1 ) π / 2 Output - ( Destructive )

2.6. Reproduction of Quantum Statistics

This geometric rotation mechanism perfectly explains interferometric experiment results: - No state superposition necessary, Purely geometric transformations of probabilistic parameters, and Exact reproduction of predicted quantum statistics.
The interferometer thus appears as a device of probabilistic transformation through rotation, rather than a revealer of ontological superpositions, preserving a totally realistic and local interpretation of quantum phenomena.

3. Reinterpreting Wave-Particle Duality (The Young’s Slits)

: distance from extended source → plane of the slits, L : distance slits → screen, a : effective width of a slit, b : distance between the centers of the two slits, λ : wavelength (or de Broglie wavelength), x : transverse coordinate on the screen.

3.1. Standard quantum-optical derivation (reference model)

This section recalls the standard quantum-optical (or classical wave) derivation of the interference formula, based on the simultaneous superposition of two fields and explicit temporal averaging. It serves as a reference framework against which the event-by-event formulation introduced later will be compared.
We start from two real time-dependent contributions coming from the two “paths”:
E 1 ( t ) = E 01 cos ( ω t + ϕ 1 ) , E 2 ( t ) = E 02 cos ( ω t + ϕ 2 ) ,
where ϕ 1 , ϕ 2 include the spatial dependence (position x) and the path difference Δ ϕ = ϕ 2 ϕ 1 .
The detector measures a power averaged over a time window long compared with the period 2 π / ω . We denote temporal averaging by · t . The instantaneous total intensity (real field) is
I tot ( t ) = ( E 1 ( t ) + E 2 ( t ) ) 2 .
Averaging gives:
I ( x ) = I tot ( t ) t = E 1 2 ( t ) t + E 2 2 ( t ) t + 2 E 1 ( t ) E 2 ( t ) t .
Computation of the terms (time average) and for the cross term, using the identity cos A cos B = 1 2 cos ( A B ) + cos ( A + B ) and the vanishing of the fast oscillating terms:
E 0 i 2 cos 2 ( ω t + ϕ i ) t = E 0 i 2 2 I i ( x ) , i = 1 , 2 , E 1 ( t ) E 2 ( t ) t = E 01 E 02 2 cos ( ϕ 1 ϕ 2 ) = I 1 I 2 cos Δ ϕ .
Collecting terms:
I ( x ) = I 1 ( x ) + I 2 ( x ) + 2 I 1 ( x ) I 2 ( x ) cos Δ ϕ ( x )
To account for partial coherence (extended source, fluctuations, etc.) one introduces the complex degree of coherence γ 12 ( x ) (with modulus 1 ), hence the commonly used form:
I ( x ) = I 1 ( x ) + I 2 ( x ) + 2 γ 12 ( x ) I 1 ( x ) I 2 ( x ) cos Δ ϕ ( x )
Practical remarks:
  • the temporal average · t removes terms like cos ( 2 ω t + ) ;
  • for a uniform source at large distance, Van Cittert–Zernike gives V ( d ) = sinc π b d λ = | γ 12 ( x ) | ;
  • experimentally V is measured by V = ( I max I min ) / ( I max + I min ) .

3.2. Physical Limitations of the Simultaneity Postulate

It should be noted that the temporal average · t only removes terms such as cos ( 2 ω t + ) if one assumes that the events occur simultaneously—meaning the probability field passes through both slits at the exact same time. Under this postulate, the formula I tot ( t ) = ( E 1 ( t ) + E 2 ( t ) ) 2 is not an independent proof matching experimental results, but rather the logical consequence of the assumption that fields traversing the slits at the same moment must interfere; this is a petitio principii (circular reasoning). While it is logical under this postulate that one cannot simply use I tot ( t ) = E 1 ( t ) 2 + E 2 ( t ) 2 , the situation changes if we assume that passages occur at different times: E 1 ( t 1 ) = E 01 cos ( ω t 1 + ϕ 1 ) and E 2 ( t 2 ) = E 02 cos ( ω t 2 + ϕ 2 ) . In such a case, the standard identity E 0 i 2 cos 2 ( ω t + ϕ i ) t = E 0 i 2 / 2 I i ( x ) would no longer be applicable, as the averaging process would involve distinct temporal variables t i :
E 0 i 2 cos 2 ( ω t + ϕ i ) t E 0 i 2 2
In the standard postulat, the simultaneity assumption is precisely what allows the fast-oscillating terms to vanish, leaving only the static interference pattern. Consequently, a reformulation is necessary, particularly since recent advancements in “Time-Domain Young’s Slit” experiments e.g., [16] have demonstrated that the temporal delay between paths is a determining physical factor in the formation of the pattern, directly challenging the validity of simple temporal averaging.

3.3. New model: event-by-event

Unlike the standard derivation recalled above, the model developed in this paper does not assume simultaneous coexisting fields nor an a priori temporal averaging. The following sections present an alternative event-by-event formulation where modulation arises from temporal correlations of individual emissions rather than from an E 1 E 2 cross-term.
No temporal averaging is introduced at this stage. The description is strictly event by event.
The contributions associated with the two slits are not assumed simultaneous. We consider two distinct emissions reaching the screen at different times t 1 and t 2 .
E 1 ( t 1 ) = E 01 cos ( ω t 1 + ϕ 1 ) , E 2 ( t 2 ) = E 02 cos ( ω t 2 + ϕ 2 ) ,
We square each contribution separately at its respective arrival time:
E 1 2 ( t 1 ) = E 01 2 cos 2 ( ω t 1 + ϕ 1 ) = E 01 2 2 1 + cos ( 2 ω t 1 + 2 ϕ 1 ) ,
We define the base intensities:
I 01 E 01 2 2 , I 02 E 02 2 2 .
The total intensity detected for an event pair is the sum of the individual impacts:
I new ( x , t 1 , t 2 ) = I 1 ( x ) 1 + cos ( 2 ω t 1 + 2 ϕ 1 ( x ) ) + I 2 ( x ) 1 + cos ( 2 ω t 2 + 2 ϕ 2 ( x ) ) .
The simplified form (modulated product):
I new ( x , T sum , Δ t ) ( I 1 ( x ) + I 2 ( x ) ) 1 + cos ( ω T sum + ϕ sum ) cos ( ω Δ t + Δ ϕ ) .
This formulation explicitly separates:
  • diffraction ( sinc 2 ),
  • temporal modulation V ( T sum ) = cos ( ω T sum + ϕ sum ) ,
  • relative phase including geometric phase Δ ϕ ( x ) and temporal shift ω Δ t .

3.4. Particular symmetric case I 01 = I 02 = I 0

I ( t 1 , t 2 ) = 2 I 0 + I 0 cos ( 2 ω t 1 + 2 ϕ 1 ) + cos ( 2 ω t 2 + 2 ϕ 2 ) .
Using the trigonometric identity cos a + cos b = 2 cos a + b 2 cos a b 2 , and defining the sum and difference of times T sum = t 1 + t 2 , Δ t = t 1 t 2 and ϕ sum = ϕ 1 + ϕ 2 we obtain:
I ( t 1 , t 2 ) = 2 I 0 + 2 I 0 cos ( ω T sum + ϕ sum ) cos ( ω Δ t + Δ ϕ ) .
This result is obtained without interaction between fields and without any E 1 E 2 cross-term.

3.5. Role of time and randomness

In the single-slit case, a single phase term cos ( ω t + ϕ ) appears, whose mean cos can cancel. In the double-slit case, the two conjugate terms cos ( 2 ω t 1 + 2 ϕ 1 ) and cos ( 2 ω t 2 2 ϕ 2 ) preserve a relative structure protected by the geometric offset.
cos ( 2 ω t 1 + 2 ϕ 1 ) = 0 2 ω t 1 + 2 ϕ 1 = π 2 + n π , cos ( 2 ω t 2 + 2 ϕ 2 ) = 0 2 ω t 2 + 2 ϕ 2 = π 2 + m π .
These conditions cannot be satisfied statistically under temporal noise. Thus, randomness cannot suppress the whole modulation.

3.6. Conclusion

In a single slit, the absence of a relative structure makes the modulation fully vulnerable to temporal noise. In the double slit, the temporary term introduces a robust relative structure, allowing fringes to exist, at least transiently, even in the presence of temporal randomness. Simultaneity is not required; it is the relative geometry of the paths that protects the spatial modulation.

4. Model Validation via Statistical Classical Mechanics

4.1. Virial Relation and Statistical Force Balance

The Virial Theorem establishes a general statistical relation between kinetic and potential energies for bound systems. For a central Coulomb potential V ( r ) 1 / r , it reads
2 T = V ,
where brackets denote ensemble or time averages. Using classical expressions, this relation becomes :
1 2 m v 2 = 1 2 e 2 4 π ϵ 0 r .
Rewriting it in radial form yields the equivalent statistical identity
m v 2 r = e 2 4 π ϵ 0 r 2 ,
which formally corresponds to an equality between average centrifugal and electrostatic forces. This relation characterizes a condition of statistical equilibrium and does not rely on the existence of well-defined particle trajectories.

Interpretative Implications.

The emergence of such equilibrium relations from purely statistical considerations highlights a key conceptual point: constraints governing ensemble averages can reproduce structures often interpreted as intrinsically quantum. When these statistical relations are implicitly promoted to ontological statements about individual particles or single events, interpretative paradoxes naturally arise.
Within the present framework, quantum mechanical formalisms are viewed as providing accurate statistical predictions for measurement outcomes, while individual physical events remain local and realist. The appearance of non-locality, superposition, or indeterminism is thus traced back to the attribution of physical reality to quantities that are fundamentally statistical in nature.

Discussion

Electrodynamic Exchange Model: Deterministic Light-Polarizer Interaction

Within the framework of a deterministic and corpuscular physical approach, light radiation is modeled as a stream of discrete, indivisible particles: photons. Each photon possesses, from the moment of its emission by the source, a linearly defined spatial polarization vector, corresponding to the strict geometric orientation of its electromagnetic dipole moment. The photon does not exist in any indeterminate state of superposition: its physical variables (energy E = h ν and oscillation angle θ ) are local, fixed, and real properties throughout its propagation in a vacuum.
The polarizing device (such as a stretched polymer film) constitutes a macroscopically anisotropic material medium. It is characterized by a network of long, conductive molecular chains aligned parallel to one another. Within these macromolecular structures, valence electrons possess a one-dimensional degree of freedom: they can move freely along the axis of the polymers (conduction axis), but their motion is highly constrained and blocked in the perpendicular direction (transmission axis).
Upon the impact of the photon flux on the molecular network, the interaction between the oscillating electric field of each photon and the electrons of the material is governed by a direct electrodynamic coupling. Depending on the photon’s initial angle of incidence θ relative to the physical axes of the filter, three exclusive interaction channels emerge:
  • The Blocking Absorption Channel (No Passage - 0%): When the component of the photon’s electric field is strictly aligned with the conduction axis of the molecules, the photon is fully absorbed by the free electrons. These charges enter into kinetic resonance along the polymer chains, and the energy is entirely dissipated as thermal agitation (heat) within the crystalline lattice (or reflected depending on the type of polarizer). The incident photon is annihilated.
  • The Direct Transmission Channel (Total Passage - 100%): When the photon’s electric field vector is perfectly perpendicular to the conduction axis (thus strictly aligned with the transmission axis), the photon is absorbed by the receiving electrons. Due to the physical constraints of the material, these electrons can only oscillate along the single axis allowed by the filter’s geometry. Behaving as oscillating dipoles (microscopic antennas), they systematically re-emit a new secondary photon.
  • The Partial Probabilistic Filtering Channel (Passage according to Malus’s Law): When the component of the photon’s electric field exhibits an intermediate oblique angle, the interaction obeys a probabilistic distribution.
    A first portion of these photons is absorbed by the electrons and then thermally dissipated (or reflected).
    The second portion is also absorbed but triggers a re-emission.
    This passage percentage is determined by the underlying internal states (hidden variables of both the photon and the electron, possibly their respective internal angular momenta at the exact moment of absorption), macroscopically resulting in the passage percentages predicted by Malus’s law for each initial polarization angle of the photon.
Since the oscillation vector of the emitting electron (in both the transmission and re-emission channels) is strictly dictated by the filter’s anisotropy, every re-emitted photon de facto adopts the exact angle of this transmission axis. The emerging radiation is thus entirely converted by the material medium. The filter acts as a state transformer by substitution: it permanently eliminates the fraction of non-compliant photons and regenerates the remainder as a beam of perfectly homopolar secondary photons.

Bell’s Formalism and Information Disintegration

Just as the temporal integration typically applied to the double-slit experiment yields an ensemble average that obscures the discrete dynamics of individual particle impacts, a parallel methodological constraint arises in the standard statistical treatment of entanglement. In both instances, continuous integration operates as a macroscopic smoothing procedure, which inherently omits the localized fine structure of individual physical interactions. To examine this parallel within Bell’s formalism, consider a pair of photons sharing the same hidden variable x, with two polarizers oriented at angles a and b. The local probability of joint transmission is expressed as:
P ( x ) = cos 2 ( x a ) cos 2 ( x b )
Using the trigonometric identity:
cos 2 θ = 1 + cos ( 2 θ ) 2 , P ( x ) = 1 4 1 + cos ( 2 x 2 a ) + cos ( 2 x 2 b ) + cos ( 2 x 2 a ) cos ( 2 x 2 b )
Then, applying the product-to-sum identity cos A cos B = 1 2 cos ( A B ) + cos ( A + B ) , we find:
P ( x ) = 1 4 + 1 4 cos ( 2 x 2 a ) + 1 4 cos ( 2 x 2 b ) + 1 8 cos ( 2 a 2 b ) + 1 8 cos ( 4 x 2 a 2 b )
The average over a complete cycle is defined by the integral:
P ¯ = 1 2 π 0 2 π P ( x ) d x , w h i c h e x p a n d s l i n e a r l y i n t o :
P ¯ = 1 4 + 1 8 π 0 2 π cos ( 2 x 2 a ) d x + 1 8 π 0 2 π cos ( 2 x 2 b ) d x + 1 8 cos 2 ( a b ) + 1 16 π 0 2 π cos ( 4 x 2 a 2 b ) d x
Since the integration of these sinusoidal functions over a whole number of periods evaluates to zero:
0 2 π cos ( 2 x 2 a ) d x = 0 , 0 2 π cos ( 2 x 2 b ) d x = 0 , 0 2 π cos ( 4 x 2 a 2 b ) d x = 0
all terms containing the hidden variable x explicitly vanish under integration, leaving the final correlated result:
P ¯ = 1 4 + 1 8 cos 2 ( a b )
This calculation demonstrates that a single hidden variable may simultaneously appear under several related functional forms, such as x a , x b , and x a b , without their mutual dependence preventing integration. By contrast, when two variables x and y are introduced, a uniform integration over the product space leads to a different result, typically P ¯ = 1 / 4 , when they are treated as independent, even in situations where a functional constraint may exist between them. The question then becomes the following: what mathematical criterion allows us to regard the correlation between x a , x b , and x a b as merely part of the integrand, while considering that a dependence explicitly written as y = x a should modify the integration space or prevent x and y from being treated as free variables? In other words, does an intrinsic distinction exist between a restriction “within the integrand” and a relation “within the integration space,” or does this distinction arise solely from the adopted formalism? The theory of measure disintegration provides a preliminary answer by showing that the same dependency structure can be described in several mathematically equivalent ways: either by reducing the number of free variables, or by retaining all variables while concentrating the measure on the subset satisfying the constraint. This interdependence is therefore not necessarily attached to the integrand or to the integration space in any absolute sense; it may instead be carried by the measure itself. The coarea formula points in the same direction by establishing a rigorous connection between integration over the ambient space and integration over subsets defined by constraint relations.
Consequently, Bell’s local separability assumption, written in the form P ( A , B x ) = P ( A x ) · P ( B x ) , should not be regarded as an absolute mathematical necessity, but rather as a formalization hypothesis whose validity depends on the actual physical constraints of the system under consideration. In a model where several local responses depend on a common underlying parameter, the terms of the integrand may be strongly correlated by construction, and this correlation should not be confused with conditional independence. The decisive issue is therefore not integration itself, but the manner in which the measure and the underlying coupling are defined prior to factorization. From this perspective, factorization may be interpreted as a disintegration of information: a formal operation that separates, within the mathematical description, what remains interconnected within the physical structure of the model.
It should also be emphasized that the variable x is not necessarily reducible to a simple axial rotation over the interval [ 0 , 2 π ] . If x carries additional physical information, particularly of a wave-like nature, then continuous integration over x may lead to the elimination of interaction terms between x and the local parameters a and b, as well as their global interdependence. The fundamental question then becomes whether this disappearance reflects a genuine physical property of the system or an informational loss induced by the chosen formalization hypothesis.

Conclusions

Quantum Mechanics (QM) describes the collective movements and statistical distributions of particles very well. However, applying it to a single individual particle inevitably leads to measurement problems, seemingly ’magical’ faster than light relations, non-locality, or state duality. The error lies in applying a statistical law of the ensemble -not designed to describe a single individual particle— to the ontological scale of the individual or the application of probabilities established based on temporal averages to an instantaneous event; this leads to an erroneous interpretation. Conversely, applying laws such as Malus’s Law for photons (or equivalent laws for other particles) restores realism and locality for each particle while faithfully reproducing the probabilities observed for the entire group:
- A single particle experiences a binary outcome, either passing or failing to pass through a polarizer. Governed by Malus’s law and the strict mathematical symmetry cos 2 ( a b ) = cos 2 ( b a ) , this establishes that polarizers can be arranged in any sequential order without altering the total passage probabilities.
- Two twin particles emitted with the same initial orientation can yield the same outcome for a given polarizer and, even when sent separately, exhibit the same passage statistics through two polarizers.
- A group of particles can produce interference-like patterns while each particle remains a localized corpuscle: particle by particle emissions yield individual impacts, whose accumulation forms a structured distribution. In a single slit this structure is destroyed by temporal noise, whereas in the double slit the temporal term provides a relative reference that stabilizes the modulation with no simultaneity required.
On this basis, it is appropriate and scientifically healthy to reassess long-standing interpretational claims. Just as scientific thought corrected geocentrism when empirical and conceptual grounds required it, so too may physics benefit from re-examining the ontological leaps made when ensemble statistics were promoted to statements about individual instantaneous reality. Ending this “quantum geocentrism” would open the way to rebuilding a coherent, local and realistic conceptual foundation for physics, one that preserves the empirical success of QM while eliminating unnecessary metaphysical baggage.

Experimental Tests of Locality

Bell Experiments: Locality Tested through Polarization Correlations

To distinguish the local realistic model (based on Malus’s Law and particles produced with an identical initial orientation λ ) from the non-local quantum model, the following experiments are proposed:
  • Test by Alternating Marginals (2 Polarizers Case): In a standard Bell experiment, alternating or manipulating the marginal probability distributions (e.g., on a single branch should lead to the loss of the Bell inequality violation at at 35% of marginal bias). This would validate that the violation is conditioned by the initial probabilities of the local state λ , and not by an unalterable non-local correlation.
  • Test by Alternating Marginals (4 Polarizers Case): Using the four-polarizer scenario ( a 1 , b 1 and a 2 , b 2 ), alternating the marginals should lead to the elimination of inequality violations for the inter-branch correlation ( E ( θ a 1 , θ b 2 ) ), while retaining the same sequential probabilities for the intra-branch ( P ( a 1 + , b 1 + ) ). Furthermore, if the order of the polarizers is reversed on one of the branches, the sequential passage probabilities should remain identical, demonstrating the independence of the measurement order for the individual particle relative to non-local correlations.
  • Prediction regarding Two Physically Distinct Emitters: Set two physically distinct emitters in the same way so that they each produce particles with the same initial orientation λ . Testing the Bell correlation between a photon from Emitter A and a photon from Emitter B (which are therefore not from the same production pair) should also show a violation of Bell’s inequalities. Such a result would prove that the observed correlation is due to the local nature of the production (the identical initial state λ ) and not to a non-local entanglement specific to a single pair.

Young Experiments: Locality Tested through Long-Term Interference

The question of the fundamental role of ω t in fringe formation is not settled by an a priori interpretation, but by a clear experimental criterion based on the long-term particle by particle experiment to observe the asymptotic evolution of fringe visibility, with two experimental outcomes possible:
  • Progressive disappearance of fringes at long times. If, as the number of events increases, fringes become less and less discernible until they vanish into statistical noise, then the temporal factor ω t must be identified as the dominant parameter of the modulation. In this case, the fringes do not correspond to a real interaction between two simultaneous waves, but to a transient modulation linked to the temporal correlation of emissions. The most probable theory is that the wave is associated with an internal periodic dynamics (parameterized by ω ). (E.g.: a sinusoidal internal orbit (orbital frequency w) — energy rotating around an empty center for the photon, and around a confined energy or massive center m 0 for the electron.)
  • Indefinite persistence of fringes. If, on the contrary, fringes remain perfectly discernible even at very long times, then the modulation cannot be attributed to a transient temporal effect. This implies the existence of a coherent field associated with the particle ( probably the Vector Potential A (consistent with the Aharonov-Bohm effect [1])), able to interfere with itself when two slits are open, this theory implies a finite “interaction distance”: if the slits are separated beyond the physical extent of the particle’s field, or if another particle is too distant, their respective surroundings fields no longer overlap or correlate. This suggests that interference is not the result of an abstract wave superposition, but an event-wise process governed by the temporal and spatial correlation of the Vector Potential as it traverses the slits.
  • Prediction on phase drift and technical instabilities
    Unless emission is performed at a regular interval corresponding to frequency f = ω / 2 π , one predicts a systematic fringe shift over time. The internal temporal phase eventually causes a spatial drift of the modulation. On macroscopic time scales, this drift produces a constant displacement of fringe positions which, by statistical accumulation, ends up smoothing the distribution.
    What experimenters [3,17] identify as “technical instabilities” or “environmental drifts” during prolonged recordings could in fact constitute evidence of a fundamental temporal dephasing process. The disappearance of the pattern at “infinite time” would therefore not be an experimental defect, but a confirmation of the event-wise and temporal nature of interference.

Author Contributions

H.C. conceived the research program, developed the theoretical framework, implemented all numerical simulations, and wrote the manuscript. The manuscript dataset is archived and citable via Zenodo: https://doi.org/10.5281/zenodo.17929338. A preliminary version of this manuscript is available as a preprint: https://www.preprints.org/manuscript/202602.1558.

Acknowledgments

The author acknowledges the use of open-source software packages; the simulation codes and datasets generated during this study are available in the GitHub repository: https://github.com/Young-Simulation/simulation-/actions.

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