[
    {
        "id": "thesis:17869",
        "collection": "thesis",
        "collection_id": "17869",
        "cite_using_url": "https://resolver.caltech.edu/CaltechTHESIS:02062026-212938424",
        "primary_object_url": {
            "basename": "Thesis_JunjieYang.pdf",
            "content": "final",
            "filesize": 2602628,
            "license": "other",
            "mime_type": "application/pdf",
            "url": "/17869/2/Thesis_JunjieYang.pdf",
            "version": "v5.0.0"
        },
        "type": "thesis",
        "title": "Scalable Ab Initio Quantum Many-Body Methods for Crystalline Materials",
        "author": [
            {
                "family_name": "Yang",
                "given_name": "Junjie",
                "orcid": "0000-0002-6726-6538",
                "clpid": "Yang-Junjie"
            }
        ],
        "thesis_advisor": [
            {
                "family_name": "Chan",
                "given_name": "Garnet K.",
                "orcid": "0000-0001-8009-6038",
                "clpid": "Chan-Garnet-K-L"
            }
        ],
        "thesis_committee": [
            {
                "family_name": "Cushing",
                "given_name": "Scott K.",
                "orcid": "0000-0003-3538-2259",
                "clpid": "Cushing-Scott-K"
            },
            {
                "family_name": "Chan",
                "given_name": "Garnet K.",
                "orcid": "0000-0001-8009-6038",
                "clpid": "Chan-G-K"
            },
            {
                "family_name": "Sharma",
                "given_name": "Sandeep",
                "orcid": "0000-0002-6598-8887",
                "clpid": "Sharma-Sandeep"
            },
            {
                "family_name": "Minnich",
                "given_name": "Austin J.",
                "orcid": "0000-0002-9671-9540",
                "clpid": "Minnich-A-J"
            }
        ],
        "local_group": [
            {
                "literal": "div_chem"
            }
        ],
        "abstract": "<p>Achieving materials-specific predictions for large, realistic molecules and solids with strong electron correlations remains a long-standing challenge in quantum chemistry. This dissertation develops scalable ab initio quantum many-body methods for crystalline materials, demonstrating that rigorous optimization of theoretical approximations and numerical algorithms enables predictive computation even in strongly correlated systems. The work tackles three interconnected challenges, namely describing material-specific properties of strongly correlated superconductors, achieving linear scaling with k-points for large-scale periodic calculations, and establishing reliable methods for electron-phonon interactions. The following chapters address each challenge in turn.</p>\r\n\r\n<p>Chapter 2 demonstrates that ab initio density matrix embedding theory, combined with symmetry-breaking strategies for superconducting order parameters, reproduces experimental trends in cuprate superconductivity, including pressure and layer effects on transition temperatures. By directly solving the electronic Schr\u00f6dinger equation from material structures, these calculations capture multi-orbital covalency effects that simplified model Hamiltonians neglect, revealing their essential role in the spin fluctuations driving pairing. This predictive capability establishes a foundation for efficient computational screening of superconducting materials. Extending these calculations to larger k-point meshes and broader phase diagram explorations, however, demands more efficient computational algorithms.</p>\r\n\r\n<p>To overcome this computational bottleneck, Chapter 3 introduces interpolative separable density fitting framework. This development enables thermodynamic limit calculations with up to 1000 k-points, as validated on diamond, carbon dioxide, nickel monoxide, and cuprate systems. Integration with density matrix embedding theory and local natural orbital methods further yields converged ground-state energies from accurate correlated wavefunction methods such as CCSD(T) for crystalline materials in the thermodynamic limit. With computational efficiency established, the remaining challenge lies in extending the theoretical framework beyond purely electronic degrees of freedom.</p>\r\n\r\n<p>Chapter 4 addresses this need by establishing exponential ansatz wavefunctions as competitive approaches for electron-phonon systems. Unlike previous treatments based on perturbation theory, systematic benchmarking of coupled cluster theory and variational Lang-Firsov methods on the Holstein model demonstrates, for the first time, that these approaches accurately describe polaron formation across coupling regimes when combined with appropriate reference state optimization. These results provide a foundation for incorporating phonon effects into ab initio studies of superconducting materials.</p>\r\n\r\n<p>In addition to these methodological advances, GPU acceleration and MPI parallelization enhance computational throughput, enabling efficient large-scale calculations. Together, these developments constitute a computational framework for predictive ab initio quantum many-body calculations in crystalline materials, opening new avenues for understanding and designing strongly correlated quantum materials.</p>",
        "doi": "10.7907/36ns-ht38",
        "publication_date": "2026",
        "thesis_type": "phd",
        "thesis_year": "2026"
    }
]