What question did this study set out to answer?

The aim is to explore how a bio-inspired nanotube architecture enhances quantum tunneling for deuterium.

April 15, 2026Open Access

Inner-Fractal Microtubule Phononic Resonator Enables Extreme Enhancement of D–D Quantum Tunneling

Puntos clave

The aim is to explore how a bio-inspired nanotube architecture enhances quantum tunneling for deuterium.
Introduced a five-level internal fractal structure within silicon carbide nanotubes.
Implemented co-doping with elements like B, Ti, Zr, Hf, and D for optimizing confinement.
Predicted theoretical enhancements in tunneling using phononic waveguiding principles.
Estimated a quantum tunneling enhancement factor of up to 10^34 near 8 mK.
Demonstrated potential for correlated neutron emissions and tritium production.
Highlighted excess heat and phononic coherence as indicators of tunneling enhancement.

Resumen

AbstractWe introduce a bio-inspired silicon carbide (SiC) nanotube architecture featuring five-level internal fractalstructuring. This system combines tubular phononic waveguiding with hierarchical localization, producingan enhanced phononic density of states at target terahertz frequencies. Co-doping (B, Ti, Zr, Hf, D) enablesoptimized deuterium confinement and collective modulation of the Coulomb barrier. A theoretical tunnelingenhancement of up to 1034 relative to free-space Gamow factors is predicted near 8 mK. The framework isexperimentally falsifiable through correlated neutron emission, tritium production, excess heat, and phononiccoherence signatures.

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