{"authors":[{"id":"5cc14ba7-d729-43db-8aef-b5e15363fe27","name":"Maya Nicks","nodesUserId":7178,"orcid":"0009-0009-4243-0918","role":[]}],"components":[{"id":"root","name":"root","payload":{"cid":"bafybeicpmleh4xm6q25cvnhnatqflbh7ooin36lccujwguin7h22qcue6y","path":"root"},"type":{".pdf":"pdf"}},{"id":"04387b43-821f-4fa1-89db-b3bec2817581","name":"TheMayaNicksψ_mirrorCosmologyHypothesis::ACPT-SymmetricFrameworkforBouncingCosmos.pdf","payload":{"cid":"bafkreicaojejv7x774pnduud4aiawjdmmgl5ojz4lswllw6zfz5seqg7ci","path":"root/TheMayaNicksψ_mirrorCosmologyHypothesis::ACPT-SymmetricFrameworkforBouncingCosmos.pdf","title":"Manuscript"},"starred":true,"subtype":"manuscript","type":"pdf"}],"defaultLicense":"CC BY","references":[],"researchFields":["Cosmological Parameters and Dark Energy Studies","Quantum Gravity and Noncommutative Field Theories","Theory of Relativity and Unified Field Theories"],"title":"[12D_Singularity_Echo] The MayaNicks  ψ_mirror Cosmology Hypothesis: A CPT-Symmetric Framework for Bouncing Cosmos (10/17/24)","version":"desci-nodes-0.2.0","description":"The MayaNicks ψ_mirror Cosmology Hypothesis proposes a cosmological model where the universe emerges from a symmetric bounce point, mirrored by ψ_mirror, extending backward in time. Grounded in CPT (Charge-Parity-Time) symmetry and loop quantum cosmology (LQC), this framework posits that pre-geometric quantum fluctuations reflect across the  ψ_mirror bounce, evolving recursively via LQC discreteness, iteratively refining patterns till yielding stable spacetime and matter distributions. This resolves singularities, explains baryon asymmetry, and potentially accounts for dark matter without new particles. While speculative, it aligns with established theories like the Hartle-Hawking no-boundary proposal and is testable via cosmic microwave background (CMB) asymmetries and gravitational wave observations.\n","keywords":["physics","theoretical physics","loop quantum cosmology","cosmic microwave background","quantum cosmology","cosmology","parity","gravitational singularity","quantum gravity","spacetime","universe","asymmetry","gravitation","quantum","classical mechanics","quantum mechanics","anisotropy"]}