Two Descriptions of Reality – The Coherence Scale as a Commitment Threshold

Physics is very good at telling us how things change. It gives us equations for how particles move, how waves evolve, and how systems interact. But there is a surprisingly basic question it doesn’t answer clearly:

When does something actually become a definite outcome?

For example:

• A quantum particle can exist in many possible states at once
• A chemical reaction can hover at a transition point before settling
• A neuron can receive signals without firing

At what point does one possibility stop being just “possible” and become something that has actually happened?

This paper proposes that there is a real, physical answer to that question.

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The core idea

The central claim is simple but deep:

A physical outcome is formed when a system crosses a threshold and creates an irreversible record.

Before that threshold:

• the system is still exploring possibilities
• nothing has been “decided” yet
• this is what the paper calls a proto-factual state

After the threshold:

• one outcome is fixed
• it leaves a lasting trace
• it can influence what happens next

That is what we normally call a fact

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What this changes

Traditionally, physics treats different areas separately:

• Quantum mechanics describes probabilities and superpositions
• Thermodynamics describes irreversibility and entropy
• Time is treated as something that simply flows

This paper shows that all three may come from the same underlying process:

the formation of irreversible records

• Quantum behaviour happens before the threshold (when possibilities are still open)
• Classical reality appears after the threshold (when a record is fixed)
• The arrow of time comes from the fact that these records cannot be undone

So instead of three separate ideas, you get one unified picture.

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A useful analogy

Think of it like writing in wet sand.

• Before you press your finger in, the sand could take many shapes
• As you press, it starts to take form—but could still be smoothed out
• Once the imprint is deep enough, it becomes a lasting mark

That “deep enough” point is the threshold.

Physics, according to this paper, works the same way:

• below the threshold → possibilities
• above the threshold → lasting outcomes

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Why this is new

The novelty is not in any one equation—it’s in the shift of perspective.

Physics has always described:

how systems evolve

This work focuses on:

when evolution turns into reality

That’s a different question.

And importantly, the paper doesn’t just describe this idea—it connects it to real systems:

• In chemistry, reactions can happen but not “stick” unless the environment stabilises them
• In enzymes, biological systems are tuned to make outcomes happen immediately
• In quantum experiments, repeated measurements can prevent outcomes from forming at all

These are very different fields—but they all follow the same pattern:

a system approaches a threshold, and only becomes real once it crosses it

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A testable prediction

The paper also makes a concrete prediction:

There should be a measurable gap between when something starts to happen and when it becomes a final outcome

For example:

• a proton may transfer in a reaction
• but the final stable product appears slightly later

That gap—the commitment lag—is something experiments could measure.

If it exists and behaves as predicted, it would support the whole framework.

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The bigger picture

If this idea is correct, it suggests something quite profound:

Reality is not just continuous change—it is built step by step from irreversible events.

Each “fact” adds to the history of the universe.
Time is not something separate—it is the order in which those facts are created.

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In one sentence

This paper proposes that the difference between possibility and reality is not philosophical—it is a physical threshold that can, in principle, be measured.

Why This Is Not the Measurement Problem

It is natural to interpret the present framework as a contribution to the quantum measurement problem. This would be a misunderstanding of its scope.

The measurement problem, as traditionally formulated, asks: why does a quantum system described by a superposition of possibilities yield a definite outcome when measured? It is a question internal to quantum theory, concerning the transition from the unitary evolution of the wavefunction to the appearance of classical outcomes.

The present framework addresses a more general and prior question:

When does any physical process — quantum, chemical, biological, or macroscopic — produce an irreversible record that constitutes a fact?

Measurement is one instance of this process, but it is not a special one. The same structural transition appears in:

• chemical reactions, where a transition state becomes a stable product
• enzyme catalysis, where proton transfer becomes irreversibly embedded
• biological systems, where graded signals cross thresholds to produce decisions
• condensed matter systems, where fluctuations become ordered phases

In each case, the system undergoes a period of reversible or outcome-indeterminate evolution, followed by a threshold crossing at which an irreversible record is formed. The framework identifies this transition with the condition $B_R \geq C_R$

From this perspective, the measurement problem is not a unique conceptual difficulty but a particular manifestation of a general phenomenon:

the distinction between dynamical evolution and irreversible record formation

Standard quantum mechanics treats this distinction by introducing the measurement postulate. Decoherence theory explains the suppression of interference but does not specify when a definite outcome is constituted. The present framework instead proposes that outcome formation is governed by a threshold condition that applies uniformly across all physical domains.

This reframes the role of measurement:

• Measurement is not the origin of definiteness
• It is a special case of commitment in a system engineered to cross the threshold rapidly

A detector produces a definite outcome not because it is observed, but because its coupling to a large environment drives the system immediately into the regime $B_R \geq C_R$​, ensuring rapid formation of an irreversible record.

The framework therefore does not solve the measurement problem in isolation. It dissolves its privileged status by embedding it within a broader theory of fact formation.