What does this research mean for the field?

Famous optical experiments, including delayed choice, quantum erasure, and double-slit interference, can be fully explained by classical continuous transverse wave propagation and boundary conditions without requiring quantum-mechanical concepts like wave function collapse or nonlocality. Novelty: ClaimNovelty.CONTRADICTORY. Consensus alignment: ConsensusAlignment.CHALLENGES_CONSENSUS.

What question did this study set out to answer?

This research examines whether famous quantum optical experiments can be explained without quantum mechanics.

June 20, 2026Open Access

The Path Puzzle of the Photon A Wave Interpretation of Delayed Choice, Quantum Erasure, and Double-Slit Interference

Key Points

This research examines whether famous quantum optical experiments can be explained without quantum mechanics.
Theoretical analysis of delayed choice, quantum eraser, and double-slit interference experiments.
Proposes a wave-based explanation focusing on wave propagation and boundary conditions.
Demonstrates that classical concepts can substitute for quantum mechanical ones.
Finds that light behaves as a continuous wave, influenced by detector interactions.
Shows that wave decoherence accounts for changes in interference patterns without quantum mechanics.
Concludes that quantum concepts like 'wave function collapse' are unnecessary for explaining these phenomena.

Abstract

Quantum mechanics explains famous optical experiments — delayed choice, quantum eraser, and double-slit interference — using wave function collapse, nonlocality, and observer effects, endowing photons with mysterious selectivity. This paper proves these experiments require no quantum-mechanical concepts. Light is always a continuous transverse wave — slits provide boundary conditions, detectors alter them, and changing boundary conditions modify wave propagation in space. So-called "collapse upon observation" is the irreversible energy exchange between waves and macroscopic detectors; so-called "path information destroying interference" is the inevitable consequence of wave decoherence. No particle "consciousness," no retrocausality, no wave function needed — only wave propagation and ordinary boundary conditions.

The Path Puzzle of the Photon A Wave Interpretation of Delayed Choice, Quantum Erasure, and Double-Slit Interference

Key Points

Abstract

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