Sort by
Refine Your Search
-
chips, and also virtually any future magnetism-based electronics will require large, very uniform arrays of magnetic nanostructures that may use novel spin transport phenomena to manipulate and detect
-
film materials and metamaterials based on patterned arrays of material elements. Such patterning allows lithographic control of the permittivity, permeability, and conductivity of nanoscale materials and
-
to study the process and develop new assays. The goals of this project are to develop analytical measurements based on multiplexing using chip arrays, bead based arrays, and conventional flow cytometry
-
are combined with other correlated pairs, or with coherent laser pulses, or through the use of these pulses with photon-number resolving detectors. Another possible scheme combines the outputs of arrays
-
. The NIST channel sounding measurement team specializes in the development and use of instrumentation in the 10s of GHz based on phased array antennas that is optimized to capture dynamically evolving
-
-sensitive focal plane arrays for use in CMB measurements. The sensor elements are superconducting transition-edge sensors that are read out by multiplexed SQUIDs. The research will involve the development
-
variant peptides (GVPs), while accounting for a diverse array of experimental introduced artifacts, using modern LC-MS instruments and custom software tools. Individuals with a background in proteomic
-
for collaboration with various NIST laboratories, the Center for Nanoscale Science and Technology (CNST – NanoFab Facility), and external partners exist. We also maintain an array of material and surface
-
of p-type doping in nanostructures; developing methods of making electrical contact to single nanowires or arrays of nanowires; and development of new measurement methods for quantifying nanoscale
-
device structures or into 2D and 3D crystalline arrays is required for such applications. Both research into specific assembly methods of SWCNT structures (aligned films, arrays of individualized SWCNTs