Happily sharing my research notebooks, hoping this effort makes the science accessible to someone finding the field too dark.
Always here to help. Send a message. Cheers, - Reggie
Please cite the arXiv papers associated with the notebooks if the codes were helpful in any way. Thank you.
Summary description of notebooks (latest on top)
*Mathematica codes often use the xAct package and its derivatives xPert, xCoba, and xPand.
(2023/01) supp_ntbks_arxiv.2212.02203: python notebooks for Hubble constant selection with ABC/MCMC (arXiv:2212.02203)
(2022/04) supp_ntbks_arxiv.2211.05482: jupyter notebooks for ABC analysis of XCDM model selection and parameter estimation (arXiv:2211.05482)
(2022/03) supp_ntbks_arxiv.2208.07663: Notebooks for calculation of AdS black hole metric and entropy in EFT of gravity (arXiv:2208.07663)
(2022/02) supp_ntbks_arxiv.2202.08672: Mathematica notebooks for analytic and numerical analysis of nondegenerate self-tuning models (arXiv:2202.08672)
(2022/01) supp_ntbks_arxiv.2202.08460: Mathematica notebook for studying black holes in tensor-vector-scalar theory (arXiv:2202.08460)
(2021/09) supp_ntbks_arxiv.2111.11761: jupyter notebook for studying quantum-corrected telerapallel cosmology with background observation (arXiv:2111.11761)
(2021/08) supp_ntbks_arxiv.2111.08289: jupyter notebook for parametric and nonparametric analyses of cosmological data hinting at dark energy evolution (arXiv:2111.08289)
(2021/07) supp_ntbks_arxiv.2108.02500: Mathematica notebooks for well-tempered Minkowski vacuum solutions in Teledeski gravity (arXiv:2108.02500)
(2021/06) supp_ntbks_arxiv.2107.08762: Mathematica notebooks for Well-Tempered Teledeski Cosmology (arXiv:2107.08762)
(2021/05) supp_ntbks_arxiv.2106.08688: jupyter notebooks using Gaussian processes, approximate Bayesian computation, and genetic algorithm for the reconstruction of Hubble data (arXiv:2106.08688)
(2021/04) supp_ntbks_arxiv.2105.12970: friendly two-part jupyter notebook for reconstructing Horndeski gravity via the Gaussian processes (arXiv:2105.12970)
(2021/03) supp_ntbks_arxiv.2109.08508: Mathematica code for inflationary quantum dynamics using a classical-quantum correspondence (arXiv:2109.08508)
(2021/02) supp_ntbks_arxiv.2103.02311: supplementary Mathematica notebooks for arXiv:2103.02311 (Gravitational wave signatures from dark sector interactions)
(2021/01) supp_ntbks_arxiv.2101.00965: supplementary Mathematica notebooks for arXiv:2101.00965 (Self-tuning kinetic gravity braiding: Cosmological dynamics, shift symmetry, and the tadpole)
(2020/06) supp_codes_arxiv.2007.06006: supplementary Mathematica notebooks for arXiv:2007.06006 (Stealth black hole perturbations in kinetic gravity braiding)
(2020/05) quadratic_action_kgb: derivation of the second-order action for scalar and tensor perturbations in kinetic gravity braiding using xPand
(2020/04) xact_workshop_2020: Mathematica slides for field theory using xAct in Gravity Group's workshop in 2020
(2020/03) gg_cosmo_xact_2019: Mathematica slides and group output in cosmology and xTensor parts of the Gravity Group's workshop in 2019
(2020/02) integration_cosmo_dynamics: jupyter notebooks for (i) obtaining the universe's scale factor from the Friedmann equation (ii) studying scalar field dynamics in an expanding spacetime
(2020/01) thesis_notebooks: collection of notebooks used in my PhD thesis "Compact Objects, Cosmologies, and Gravitational Perturbations in Scalar-Tensor Theories of Gravity"
This collection of notebooks can be cited as:
@misc{ reggie_bernardo_4810864, author = { Reggie Bernardo }, title = {{ reggiebernardo/notebooks: dark energy research notebooks }}, year = {2021}, publisher = {Zenodo}, howpublished = {\href{ https://doi.org/10.5281/zenodo.4810864 }{ 10.5281/zenodo.4810864 }} }