Higgs-Enhanced Proton-Antiproton Annihilation and Quantum Fluctuation-Induced Micro-Black Hole Formation at LHC Energies
Abstract
Chur Chin
We investigate the possibility of micro-black hole (μBH) production through Higgs-enhanced quantum fluctuations during high-energy proton–antiproton annihilation events at the Large Hadron Collider (LHC). By examining the quantum gravitational effects amplified by electroweak symmetry breaking and non-linear vacuum excitations, we evaluate whether the current energy supply (~13 TeV) and quantum suppression constraints preclude or allow semi-classical black hole formation. Our results suggest that while direct Schwarzschild black hole production remains elusive under standard quantum gravity thresholds, Higgs field fluctuations can lower the effective Planck scale in extra-dimensional models, making μBH formation marginally accessible at LHC. We model the entropic flux decay and propose observable decay spectra (e.g., Hawking-like radiation signatures) and discuss the role of Higgs-matter coupling in curvature spike amplification.
