Join us as we explore a variety of porous materials and discover how their surface area and porosity play pivotal roles in enhancing material performance across a spectrum of applications spanning catalysis, separations, drug delivery, and energy storage. This engaging workshop is designed to equip participants with a comprehensive understanding of the key physical and chemical properties that influence material functionality.
This session combines theoretical insights with practical knowledge, offering an in-depth overview of the instrumentation and techniques for characterizing porous materials. Explore novel analytical techniques implemented to maximize efficiency with advancements in measurement time, reproducibility, and modeling of pore structures. Don't miss the highlight of our workshop – a live demonstration with the Belsorp Mini X BET surface area analyzer, where you'll witness cutting-edge technology in action, providing a hands-on experience to illustrate how the lightest, smallest, and fastest multi-point BET analyzer can benefit your characterization needs.
Whether you're a seasoned professional seeking to refine your expertise or a newcomer eager to explore the vast possibilities of porous materials, this workshop is your gateway to unlocking new opportunities for material optimization. Register now to embark on a journey of discovery and innovation. Light refreshments and lunch are provided.
Below you will find more information regarding registration and time schedule.
Professor Alex Neimark Ph.D., professor at Rutger’s University
Professor Alex Neimark is a distinguished professor at Rutger’s University. His research interests cover a broad spectrum of topics in thermodynamics, statistical mechanics, and molecular simulation of nanoporous and nanostructured materials. We attempt to better understand the specifics of the behavior of nanophases - small volumes of fluid confined to surfaces or nanopores. Due to their nanometer size, comparable with the size of individual molecules and molecular aggregates, the classical methods of thermodynamics and fluid dynamics do not work for such small systems. The goal is to determine the limits of applicability of the classical methods and to develop novel theoretical and multiscale molecular simulation methods to study nanophase equilibria and transitions, adsorption, interfacial transport, self-assembly, wetting, and other processes, which involve interactions of fluids and biomolecules with nanomaterials. Neimark’s research stands out for its versatility and a prolific mixture of fundamental and industry-oriented projects. It is distinguished by a direct focus on practical engineering systems and experimental studies employed for the validation and confirmation of theoretical models. The results have important industrial applications in nanobiotechnology, adsorption separations and catalysis, and theory-informed design of novel nanomaterials. The current projects include two types of nanomaterials: solid nanoporous materials and soft self-assembled surfactant, polymeric, and nanoparticle systems.
Garrett Taggart, Ph.D., Microtrac BEL Applications Scientist
Dr. Garrett Taggart earned his Ph.D. in chemistry at the University of Delaware synthesizing novel metal-organic materials for gas storage applications. His research focused on identifying how small changes to ligand functional groups influence the physical properties of the final material such as stability, solubility, porosity, and selectivity regarding gas adsorption. He now is an applications specialist for Microtrac, where he collaborates with and trains researchers on new physisorption and chemisorption techniques. He specializes in characterization techniques such as helium pycnometry, manometric gas adsorption, mercury porosimetry, and dynamic flow adsorption instrumentation.
December 4th 2024
10:00 AM – 03:00 PM EST
Rutgers University
Engineering Building, Wing C,
Room C-233
123 Bevier Rd, Piscataway, NJ 08854