Search Results
Facilities and Engineering Services
Professor, Chemistry
This project focuses on developing fundamental bioinspired approaches for creating self-assembled mesoscale two- and three-dimensional (2D and 3D) assemblies of meta-atoms that can serve as functional optical metamaterials.
This FWP develops new theories and computational methods to significantly accelerate scientific discoveries to support the mission of the Department of Energy’s Basic Energy Science and of Ames National Laboratory.
Our major research goal is to uncover the underlying electronic, atomic, and microscopic interactions in novel rare-earth intermetallic materials with extraordinarily strong coupling between the magnetic, electronic, and lattice degrees of freedom that drive remarkable responsiveness to external stimuli, like temperature, pressure, and magnetic field.
The proposed research holds the potential to significantly advance our comprehension and manipulation of coherence and dynamic processes that mediate exotic transport phenomena, collective behaviors, and quantum functionalities.
This mission of the MIEQM FWP is to understand phenomena when topological electronic bands on frustrated lattices are intertwined with magnetism.
This project explores the foundational theoretical understanding, numerical analysis, design, fabrication, and characterization of metamaterials, and their feasibility for technological applications, and targets current fundamental problems and opportunities in controlling light with matter and matter with light.
The purpose of Ames National Laboratory’s materials solid-state nuclear magnetic resonance spectroscopy (SSNMR) program is to advance the science of semiconductor nanoparticles and atomically thin 2D materials that can fulfill needs related to microelectronics, energy storage/conversion, quantum information, sensing, and separations/purifications.