Sort by
Refine Your Search
-
chemistry which provides certified reference materials for pH and acidimetric measurements. We are recruiting applicants to advance our electrochemistry reference materials program to support the development
-
microfluidic networks.Our goal is to develop systems that enable accurate, high-throughput, and dynamic measurement of materials in flow, which will, for example, improve the ability to specify composition and
-
various government laboratories to elucidate mechanisms of protein binding to BLMs. We comprise researchers with a broad range of expertise and are actively developing advanced biochemical and biophysical
-
are needed to support the clinical testing community and manufacturers of working standard materials. Challenges lie in developing relevant standards in a timely fashion to support new clinical targets and
-
determination of marijuana components, development of vapor measurement technology and canine training aid materials for opioids and improvised explosives, targeted and non-targeted screening of bulk samples and
-
the integration of thermodynamic and transport properties and phase equilibria in new ways (e.g., by relating mixture viscosities to azeotropy and liquid-liquid equilibria). The goal is to develop modeling
-
prevent a true function-by-design approach to development and manufacturing. We are interested in using analytical theory, large-scale molecular dynamics (MD) simulations, and density functional theory (DFT
-
the use of laser pumping and silicon micromaching. This proejct develops compact magentic sensors than combine high sensitivity and accuracy with vector field readout and manufacturability. We design novel
-
) to develop a high-throughput technique to screen new materials for high frequency performance. As a first step, the Associate will focus on ferroelectric materials and transition metal dichalcogenides
-
, but face technical challenges to achieve their potential for high efficiency. Third generation devices are now being developed that exploit nanoscale three-dimensional (3D) structures to achieve higher