| import numpy as np | |
| import matplotlib.pyplot as plt | |
| # PUH v25: Quantum Coherence Photosynthesis Sim — Population Transfer Coherent vs Incoherent | |
| t = np.linspace(0, 2000, 500) # Time fs arb. ~ps scale | |
| coherent = np.sin(0.01 * t)**2 # Oscillatory coherent beating toy | |
| incoherent = 1 - np.exp(-t / 500) # Slow exponential incoherent hop toy | |
| plt.figure(figsize=(10,6)) | |
| plt.plot(t, coherent, label='Coherent Braid Ripple Surfing Fast Oscillatory', color='cyan', lw=2) |
Author: Brian Martell
Date: January 21, 2026
PUH v25 quantum coherence photosynthesis mechanical synchronized braid antenna chlorophyll high-density lattice incoming photon excites collective torsional modes phase-locked oscillations coherence energy surfs \xi-gradient no jitter loss decoherence ~ps experiment matches incoherent random drag slow coherent ripple ride fast near-100% efficiency reaction center mechanical substrate natural phase-locked antenna. From July 14, 2025.
| @article{engel2007, | |
| author = {Engel, Gregory S. and others}, | |
| title = {Evidence for wavelike energy transfer through quantum coherence in photosynthetic systems}, | |
| journal = {Nature}, | |
| volume = {446}, | |
| pages = {782}, | |
| year = {2007}, | |
| note = {Original quantum coherence photosynthesis evidence} | |
| } |
| % Gist-ready — upload as: puh_quantum_coherence_photosynthesis_v25.tex | |
| \documentclass[11pt,a4paper]{article} | |
| \usepackage[utf8]{inputenc} | |
| \usepackage{amsmath,amssymb,amsthm} | |
| \usepackage{siunitx} | |
| \usepackage{geometry} | |
| \usepackage{booktabs} | |
| \usepackage{xcolor} | |
| \usepackage{hyperref} | |
| \usepackage{graphicx} |
| import numpy as np | |
| import matplotlib.pyplot as plt | |
| # PUH v25: Photosynthesis Lattice Energy Printer Sim — Photon Absorption → Braid Excitation → Energy Storage | |
| t = np.linspace(0, 20, 500) # Time arb. | |
| photon_input = np.exp(-(t - 5)**2 / 2) * 10 # Incoming photon ripple pulse | |
| braid_excitation = np.cumsum(photon_input) * 0.1 # Twist tension build | |
| energy_storage = 1 - np.exp(-braid_excitation / 2) # Soliton knot storage glucose toy | |
| plt.figure(figsize=(10,6)) |
Author: Brian Martell
Date: January 21, 2026
PUH v25 photosynthesis lattice energy printer plants chlorophyll braids high-efficiency antennas capture transverse photon ripples excite twist tension \xi shift electron jump untwisting release energy locked glucose stable soliton knots direct lattice-to-chemical printer survival advantage mechanical substrate natural universal resonance all life taps lattice animals consciousness plants energy. From July 14, 2025.
| @misc{photosynthesis2025, | |
| author = {{Biology Community}}, | |
| title = {Photosynthesis Chlorophyll Photon Energy Conversion}, | |
| howpublished = {Various reviews}, | |
| year = {2025}, | |
| note = {Photon absorption electron excitation} | |
| } | |
| @misc{martell2026, | |
| author = {Martell, Brian}, |
| % Gist-ready — upload as: puh_photosynthesis_lattice_energy_printer_v25.tex | |
| \documentclass[11pt,a4paper]{article} | |
| \usepackage[utf8]{inputenc} | |
| \usepackage{amsmath,amssymb,amsthm} | |
| \usepackage{siunitx} | |
| \usepackage{geometry} | |
| \usepackage{booktabs} | |
| \usepackage{xcolor} | |
| \usepackage{hyperref} | |
| \usepackage{graphicx} |
| import numpy as np | |
| import matplotlib.pyplot as plt | |
| # PUH v25: Lattice-Shift Experiment Error Calibration Sim — Signal vs Noise Budget (Anomaly Detectable) | |
| time = np.linspace(0, 3600*10, 500) # Time s 10 hours arb. | |
| noise_floor = 1e-15 * np.random.randn(len(time)) # Total error ~10^{-15} rad toy | |
| gr_signal = 1e-15 * np.sin(2 * np.pi * time / 3600) # Weak GR linear toy | |
| puh_anomaly = 1e-12 * np.sin(2 * np.pi * time / 3600) # PUH excess ~10^{-12} toy | |
| detected = noise_floor + gr_signal + puh_anomaly # Measured signal |
Author: Brian Martell
Date: January 20, 2026
PUH v25 Lattice-Shift Experiment error calibration high-RPM rotor torsional pendulum anomaly ~10^{-12} excess GR noise thermal ~10^{-16} rad/\sqrt{Hz} seismic <10^{-14} laser ~10^{-15} total ~10^{-15} rad integrated detects >10\sigma calibration null baseline spin periodic signal mechanical substrate natural precision budget. From July 14, 2025.