A collaboration of the Simon and Schuster groups at the University of Chicago MRSEC have realized a photonic strongly interacting Mott insulator using a 1D lattice of superconducting qubits.
A collaboration of the Simon and Schuster groups at the University of Chicago MRSEC have realized a photonic strongly interacting Mott insulator using a 1D lattice of superconducting qubits.
Using analytical aberration-corrected scanning transmission electron microscopy (STEM), we studied the behavior of the electron probe propagating in SrTiO3 at sub-atomic length scales.
In this work, the complexation of ABC micelles with a model semiflexible polyion, DNA, is systematically investigated to correlate the structure of the micelle with the properties of the resulting “micelleplexes”.
The NSF-MRSEC booth was featured at the XXVII International Materials Research Congress (IMRC) in Cancun, Mexico on August 19-24, 2018 to increase awareness, promote international collaboration, and broaden participation from traditionally underrepresented groups in the National Science Foundation Materials Research Science and Engineering Center (NSF-MRSEC) program.
The NU-MRSEC has supported Joint Undertaking for an African Materials Institute (JUAMI), which is the largely NSF-funded program aimed at fostering connections between young researchers in the US and those in Eastern Africa.
The new NU-MRSEC REU+ Program enables select REU participants from small colleges to follow their summer experience with an academic quarter at Northwestern University as domestic exchange students, thereby allowing them to experience the rigor of an R1 university in a nurturing environment. REU+ students take classes and also continue their research for an additional ten weeks.
In collaboration with the Chicago Museum of Science and Industry and the Chicago Public Library, the NU-MRSEC launched the Materials Science Exhibit at the Harold Washington Library in downtown Chicago. The exhibit includes the Microscopy Gallery, which features artistic scientific images based on the latest research of nanoscale systems studied in NU-MRSEC Shared Facilities.
Traditional design approaches are insufficient for exploring the vast phase space available to protein-based biomaterials. This NU-MRSEC seed-funded project is developing a platform for biomaterials design using directed evolution, which combines genetic mutation and protein synthesis with high-throughput materials characterization.
The NU-MRSEC Super-Seed team has developed a method to process imine-linked 2D COF powders into thin films via reversible exfoliation. The COF powder is treated with strong acids, which causes each layer to become positively charged. This charged form is exfoliated in solvents with gentle sonication, which provides a suspension of nanosheets.
Semiconductors with both magnetic and optoelectronic properties are relevant for novel spintronic devices. With the aim of discovering new magnetic semiconductors, NU-MRSEC IRG-2 performed synthesis investigations on mixed halide-chalcogenides, resulting in the discovery of the new compound BaFMn0.5Te.