What question did this study set out to answer?

This research aims to explore the Chapagain Cycle, proposing connections between black and white holes and cosmic matter recycling.

March 16, 2026Open Access

Chapagain Cycle: Black-White Hole Bridges and Cosmic Recycling

Key Points

This research aims to explore the Chapagain Cycle, proposing connections between black and white holes and cosmic matter recycling.
Analyzed black hole processes via accretion and evaporation
Investigated loop quantum gravity effects at Planck scale
Predicted observational outcomes related to AGN nebulae and gravitational waves
Examined implications for dark energy and information paradox
Predicted He-3/He-4 enrichment in AGN nebulae
Identified potential high-frequency gravitational chirps from quantum bounces
Forecasted gamma-ray bursts as precursors to nebulae brightening
Suggested positronium excess near galactic centers

Abstract

Black holes process stellar matter through accretion disks and Hawking evaporation over cosmological timescales (tH ∼ 10⁶7 (M/M_⊙) ³ years). At Planck scale, loop quantum gravity triggers bounce, tunneling via ER=EPR quantum bridges to transient white holes (τ ∼ 10^-39 s). These erupt, dispersing atomic plasma that cools into star-forming nebulae over 10⁵ years. The Chapagain Cycle predicts: • He-3/He-4 enrichment (0. 05 vs Big Bang 10^-4) in AGN nebulae (JWST testable) • High-frequency gravitational chirps (10^-15 Hz) from Planck bounces (LISA) • GRB precursors to nebulae brightening (Fermi) • Positronium excess near galactic centers (ALMA) Model provides dark energy alternative via cumulative white hole outflows, resolves information paradox, and explains nebula metal enrichment without fine-tuning ΛCDM. Speculative toy model inspired by LQG bounce scenarios and ER=EPR conjecture.

Chapagain Cycle: Black-White Hole Bridges and Cosmic Recycling

Key Points

Abstract

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