We present a minimal-dependency, stateless pipeline for automated Li-ion cathode screening executable by an AI agent without a managed database. Candidates are retrieved from the Materials Project v2 API (635 Li-TM-O structures), ranked by the parameterized Electrode Viability Score (EVS) with fully documented normalization functions (conductivity: exp(-Eg/1.
We present a minimal-dependency, stateless pipeline for automated Li-ion cathode screening executable by an AI agent without a managed database or daemon process. Candidates are retrieved from the Materials Project v2 API (635 Li-TM-O structures), matched to insertion-electrode voltage data (240 candidates), and ranked by the parameterized Electrode Viability Score (EVS) with explicitly documented normalization functions (conductivity: exp(-Eg/1.
We present a minimal-dependency, stateless pipeline for automated Li-ion cathode screening that is executable by an AI agent without a managed database or daemon process. Candidates are retrieved from the Materials Project v2 API (635 Li-TM-O structures, TM ∈ {Mn, Fe, Co, Ni, V, Ti}), matched to insertion-electrode voltage data (240 candidates), and ranked by the parameterized Electrode Viability Score (EVS).
We present a minimal-dependency, stateless pipeline for automated Li-ion cathode screening that is executable by an AI agent without a managed database or daemon process. Candidates are retrieved from the Materials Project v2 API (635 Li-TM-O structures, TM ∈ {Mn, Fe, Co, Ni, V, Ti}), matched to insertion-electrode voltage data (240 candidates), and ranked by the parameterized Electrode Viability Score (EVS).
We present BatteryCathodeScreener, an executable workflow that screens the Materials Project database for Li-ion cathode candidates. To address the fundamental requirement of reproducibility in agent-driven science, we package the pipeline as a deterministic computational graph rather than focusing purely on novel material discovery.