What question did this study set out to answer?

The aim is to redefine catalysis by viewing it as a geometric phenomenon rather than a purely energetic one.

February 9, 2026Open Access

MID/QC Applied Molecular Geometry Series 1 - Catalysis as Coherence Geometry: Reaction Pathways as Geometric Reconfiguration Events

Key Points

The aim is to redefine catalysis by viewing it as a geometric phenomenon rather than a purely energetic one.
Introduced coherence corridors to analyze catalytic processes.
Examined the role of geometric compatibility in catalytic specificity.
Analyzed nanoscale surface effects and the influence of dopants on catalysts.
Assessed the persistence of catalysts in the context of geometric viability.
Catalysts reshape local coherence geometry rather than just lowering activation energy.
Geometric compatibility explains various catalytic behaviors across different scientific disciplines.
Insights into nanoscale effects and dopant roles highlight new aspects of catalyst functionality.

Abstract

This paper reframes catalysis as a geometric phenomenon within the MID/QC substrate framework. Rather than lowering activation energy, catalysts reshape local coherence geometry to stabilize transitional molecular configurations that would otherwise be non-viable. The manuscript introduces coherence corridors, explains catalytic specificity through geometric compatibility, and examines nanoscale surface effects, dopant influence, and catalyst persistence. Catalysis emerges as a question of geometric viability, unifying catalytic behavior across chemistry, biology, and materials science.

MID/QC Applied Molecular Geometry Series 1 - Catalysis as Coherence Geometry: Reaction Pathways as Geometric Reconfiguration Events

Key Points

Abstract

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