Fractal Resonance Spectrum
The "triplet of triplet" resonance pattern repeats across Hz, kHz, MHz, and GHz scales. Click any peak to zoom into its sub-structure.
What You're Seeing
Each frequency band (Hz to GHz) contains three primary resonance peaks, and each peak contains three sub-peaks — a "triplet of triplet" pattern. This self-similar structure appears at every scale, from individual tubulin proteins to whole neurons. Click any peak to zoom in and see its fractal sub-structure.
Microtubule Cross-Section
A microtubule: 13 protofilaments arranged in a hollow chiral cylinder (~25nm diameter). Sweep the driving frequency to find resonances.
Microtubule Architecture
13 protofilaments form a hollow tube with a 3-start helical lattice. The chirality (handedness) of this helix is critical — it determines how electromagnetic waves propagate along the structure. At resonant frequencies, coherent wave patterns appear along the tube, with the structure acting as a nanoscale electromagnetic waveguide.
Temporal Cascade
Filaments fire ~250μs BEFORE the membrane ionic spike. ~4 filament bursts gate each ionic spike. This challenges the classical Hodgkin-Huxley model.
The Century-Old Picture Is Wrong?
Classical neuroscience says the membrane ionic spike is the primary signal. Bandyopadhyay's team measured that cytoskeletal filaments fire 250μs before the membrane — operating in the microsecond (MHz) domain while the membrane operates in milliseconds (kHz). Approximately 4 filament bursts regulate each ionic spike's timing. Use "Flip Order" to test H4: does membrane-first produce coherent output?
Holographic Projection
Optical vortex rings emanating from a microtubule. Internal "clocks" project as distinct angular momentum states of light.
Polyatomic Time Crystals
When illuminated with polarized laser light, ordered structures inside neurons impart angular momentum to photons, creating distinct optical vortex rings. Each internal "clock" — operating at a different frequency — generates a unique ring pattern. Selective EM stimulation can brighten specific frequency components, revealing the nested clock assembly. This is the most controversial claim and needs independent replication.
Hypothesis Lab
Testable predictions from the simulation. Click a hypothesis to expand, then run computational tests.