This project estimates key cosmological parameters like the Hubble constant (H₀) and matter density (Ωₘ) using Type Ia supernova data. It involves distance modulus fitting, cosmological model calculations, and analysis of low-z and high-z supernova subsets.

Official repository for the Modular Substrate Theory (MST). Unifying alpha, H0, e, and zeta(0) via a Z/6Z substrate. Featuring 110-digit precision audits, a 10^-14 exact derivation of the fine-structure constant, and the resolution of the Hubble tension.

This program classifies the universe as flat, open, or closed based on the matter density parameter (Ωₘ) and dark energy density parameter (ΩΛ). The user enters the Hubble constant, Ωₘ, and ΩΛ, and the program uses these to determine the universe’s geometry.

this repository is for the cosmology course in the Winter of 1401. you can find out your computational homework here.

Binary console application to calculate the age of the universe based on observations,

A python package to calibrate levitt law

Presentation of the standard siren measurement of Hubble constant at Journal Club talk in Jan. 09 2018.

Breakthrough Achievement The ECC Framework successfully resolves the Hubble Tension, reducing it from 4.8σ to 1.7σ through quantum entanglement effects between photons and dark photons. This represents one of the most effective solutions to one of cosmology's biggest puzzles.

Cosmology

Estimate the Hubble constant using Pantheon+SH0ES supernova data

Re-reduced classification spectra from the ePESSTO+ survey, used in the paper:
"No rungs attached: A distance-ladder free determination of the Hubble constant through type II supernova spectral modelling."
by C. Vogl et al. (2024).

An effective field theory on a Riemann–Cartan manifold in which torsion is encoded by a scalar field, providing a geometric framework for gravity and cosmology beyond standard curvature-only models.