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CU �鶹ӰԺ’s East Campus is now home to the High-Sensitivity Low-Energy Ion Scattering (HS-LEIS) Spectrometer, a tool researchers from across the Rocky Mountain region will use for advanced materials characterization and analysis.

Teaching undergraduate-level engineering courses is always a challenge. Teaching advanced concepts via remote instruction during a historic pandemic is even harder.

Assistant Professor C. Wyatt Shields IV is the recipient of a 2022 Office of Naval Research (ONR) Young Investigator Program Award for his proposal “Mapping Immune Cell Responses to High Pressures in Decompression Illness.”

Assistant Professor C. Wyatt Shields IV is the recipient of a National Science Foundation (NSF) Faculty Early Career Development Program (CAREER) award for his proposal “Shape-Encoded Electrokinetic Particles for Multiplexed Biosensing.” This project seeks to develop a new method of early identification of disease biomarkers, while also facilitating outreach and education to students at Northglenn High School.

Six students from across the College of Engineering and Applied Science were selected as Herbst Fellows this semester, joining an elite group of scholars who embody the program’s commitment to ethical engineering study and practice.

This year marks the 25th anniversary of the revamped and retooled Chemical Engineering Design Project course — a class (re)designed to provide seniors with practical problem-solving experience and foster stronger ties to industry.

Postdocs and graduate students combined art, movement, dance and science for students from the �鶹ӰԺ Valley School District.

A Road Toward Sustainability – from Materials to Processes Speaker: Juan Manuel Restrepo-Flórez, Postdoctoral Associate University of Wisconsin-Madison Host: Will Medlin Tuesday, March 8, 2022 - 2:45 p.m.,

Computational Engineering of Materials at the Nanoscale—where “Classical” meets “Quantum” Speaker: Elizabeth Lee, Postdoctoral Researcher University of Chicago Host: Kayla Sprenger Thursday, March 3, 2022

Improved understanding of transport in concentrated electrolyte solutions has important implications for energy storage, water purification, biological applications, and more. This understanding should ideally persist across length scales: we desire both continuum-level insight into macroscopic concentration and electric potential profiles as well as a molecular-level understanding of the mechanisms governing ion motion. However, the most ubiquitous theory to describe continuum-level electrolyte transport, the Stefan-Maxwell equations, yields transport coefficients which lack clear molecular-level interpretation and cannot be easily computed from molecular simulations.