Your search keyword '"Comstock, Andrew H."' showing total 4 results

1. How the AI-assisted discovery and synthesis of a ternary oxide highlights capability gaps in materials science

Author

Montoya, Joseph H, Grimley, Carolyn, Aykol, Muratahan, Ophus, Colin, Sternlicht, Hadas, Savitzky, Benjamin H, Minor, Andrew M, Torrisi, Steven B, Goedjen, Jackson, Chung, Ching-Chang, Comstock, Andrew H, and Sun, Shijing

Subjects

Inorganic Chemistry, Chemical Sciences, Chemical sciences

Abstract

Exploratory synthesis has been the main generator of new inorganic materials for decades. However, our Edisonian and bias-prone processes of synthetic exploration alone are no longer sufficient in an age that demands rapid advances in materials development. In this work, we demonstrate an end-to-end attempt towards systematic, computer-aided discovery and laboratory synthesis of inorganic crystalline compounds as a modern alternative to purely exploratory synthesis. Our approach initializes materials discovery campaigns by autonomously mapping the synthetic feasibility of a chemical system using density functional theory with AI feedback. Following expert-driven down-selection of newly generated phases, we use solid-state synthesis and in situ characterization via hot-stage X-ray diffraction in order to realize new ternary oxide phases experimentally. We applied this strategy in six ternary transition-metal oxide chemistries previously considered well-explored, one of which culminated in the discovery of two novel phases of calcium ruthenates. Detailed characterization using room temperature X-ray powder diffraction, 4D-STEM and SQUID measurements identifies the structure and composition and confirms distinct properties, including distinct defect concentrations, of one of the new phases formed in our experimental campaigns. While the discovery of a new material guided by AI and DFT theory represents a milestone, our procedure and results also highlight a number of critical gaps in the process that can inform future efforts towards the improvement of AI-coupled methodologies.

Published

2024

2. Inverse chirality-induced spin selectivity effect in chiral assemblies of π-conjugated polymers

Author

Sun, Rui, Park, Kyung Sun, Comstock, Andrew H., McConnell, Aeron, Chen, Yen-Chi, Zhang, Peng, Beratan, David, You, Wei, Hoffmann, Axel, Yu, Zhi-Gang, Diao, Ying, and Sun, Dali

Published

2024

3. Anomalous Correlation between Thermal Conductivity and Elastic Modulus in Two-Dimensional Hybrid Metal Halide Perovskites

Author

Negi, Ankit, primary, Yan, Liang, additional, Yang, Cong, additional, Yu, Yeonju, additional, Kim, Doyun, additional, Mukherjee, Subhrangsu, additional, Comstock, Andrew H., additional, Raza, Saqlain, additional, Wang, Ziqi, additional, Sun, Dali, additional, Ade, Harald, additional, Tu, Qing, additional, You, Wei, additional, and Liu, Jun, additional

Published

2024

4. Colossal anisotropic absorption of spin currents induced by chirality.

Author

Sun R, Wang Z, Bloom BP, Comstock AH, Yang C, McConnell A, Clever C, Molitoris M, Lamont D, Cheng ZH, Yuan Z, Zhang W, Hoffmann A, Liu J, Waldeck DH, and Sun D

Abstract

The chiral induced spin selectivity (CISS) effect, in which the structural chirality of a material determines the preference for the transmission of electrons with one spin orientation over that of the other, is emerging as a design principle for creating next-generation spintronic devices. CISS implies that the spin preference of chiral structures persists upon injection of pure spin currents and can act as a spin analyzer without the need for a ferromagnet. Here, we report an anomalous spin current absorption in chiral metal oxides that manifests a colossal anisotropic nonlocal Gilbert damping with a maximum-to-minimum ratio of up to 1000%. A twofold symmetry of the damping is shown to result from differential spin transmission and backscattering that arise from chirality-induced spin splitting along the chiral axis. These studies reveal the rich interplay of chirality and spin dynamics and identify how chiral materials can be implemented to direct the transport of spin current.

Published

2024