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Spring 2015 Seminars

January 12, 2015GPS 101Kent Ridl
January 19, 2015Martin Luther King, Jr. Day
January 26, 2015

The Emerging Role of Network Analysis in Physics Education

Eric Brewe
February 2, 2015TBAAaron Feickert
February 9, 2015TBAEric Foard
February16, 2015

<Presidents' Day> Engineering Persister-Specific Antibiotics with Synergistic Antimicrobial Functions

Gerard Wong
February 23, 2015Bruce Rafert
March 2, 2015APS March Meeting 
March 9, 2015
March 16, 2015Spring Break!!
March 23, 2015TBAAlec Habig
March 30, 2015
April 1, 2015<Special Day and Location!!>Structure, Dynamics and Properties of Block Polymer DispersionsFrank S. Bates
April 6, 2015Spring Recess

April 13, 2015

April 20, 2015TBAAlfredo Alexander-Katz
April 24, 2015<Special Day!!>TBAChristos Likos
April 27, 2015
May 4, 2015TBAJessica Striker
May 5, 2015<Special Day and Location!!>A Robust Nonlinear Block Copolymer Nanoreactor-Based Strategy to Monodisperse Hairy Nanocrystals with Precisely Controlled Dimensions, Compositions and ArchitecturesZhiqun Lin
May 11, 2015Exam Week!



The Emerging Role of Network Analysis in Physics Education

Eric Brewe

Assistant Professor of Science Education,
Physics Education Research Group,
Florida Florida International University.


Monday, January 26, 2014, 3:00-4:00pm.  221 South Engineering

Join us for Refreshments at 2:30

Network Analysis is an approach to analyzing data which are relational in nature. With origins in quantitative sociology and more recent development in graph theory, Network Analysis is a rapidly growing interdisciplinary approach. The emergence of Network Analysis in education is the result of a recognition that student interactions naturally give rise to relational data, and that this has far-reaching consequences.  In this talk, I will provide several examples from physics education of how network analysis is being applied to the analysis of informal student communities, classroom communities, diagnostic tests such as the Force Concept Inventory, and even to investigate the retention and persistence of students in the physics major. 

Structure, Dynamics and Properties of Block Polymer Dispersions

Dr. Frank S. Bates

Regents Professor and Head, Department of Chemical Engineering and Materials Science, University of Minnesota


<Special Time!!>Wednesday, April 1, 2015, 3:00-4:00pm (refreshments served 2:30).

<Special Location!!>271 Batcheller Technology Center

Block copolymers belong to a broad class of amphiphilic compounds that includes soaps, lipids and nonionic surfactants. These macromolecules assemble into micelles with molecular dimensions on the order of 5 to 50 nm in size when mixed with excess solvent that preferentially solvates one block type. This presentation will explore two different aspects of block copolymer micelle formation. The fundamental thermodynamic and kinetic factors that control micelle shape and dynamics will be discussed based on small-angle x-ray and neutron scattering (SAXS and SANS) experiments and cryogenic transmission and scanning electron microscopy results. Although the structural features displayed by amphiphilic block copolymers resemble those associated with the self-assembly of lipids and simple surfactants (e.g., spherical and cylindrical micelles and vesicles) a macromolecular architecture leads to remarkably different dynamic properties, linked to a vanishingly small critical micelle concentration. As a consequence, molecular exchange is rapidly extinguished with increasing molecular weight resulting in non-ergotic behavior. These concepts have been exploited in developing a recently commercialized technology that provides immense improvements in the fracture toughness of thermosetting epoxy plastics, which also will be described.

A Robust Nonlinear Block Copolymer Nanoreactor-Based Strategy to Monodisperse Hairy Nanocrystals with Precisely Controlled Dimensions, Compositions and Architecture.

Dr. Zhiqun Lin

Professor, School of Materials Science and Engineering, Georgia Institute of Technology


<Special Time!!> Tuesday, May 5, 2015, 3:00-4:00pm (Refreshments will be served at 2:30).

<Special Location!!>271 Bachellor Technology Center

Nanocrystals exhibit a wide range of unique properties (e.g., electrical, optical, and optoelectronic) that depend sensitively on their size and shape, and are of both fundamental and practical interest. Breakthrough strategies that will facilitate the design and synthesis of a large diversity of nanocrystals with different properties and controllable size and shape in a simple and convenient manner are of key importance in revolutionarily advancing the use of nanocrystals for a myriad of applications in lightweight structural materials, optics, electronics, photonics, optoelctronics, magnetic technologies, sensory materials and devices, catalysis, drug delivery, biotechnology, and among other emerging fields. In this talk, I will elaborate a general and robust strategy for crafting a large variety of functional nanocrystals with precisely controlled dimensions (i.e., plain, core/shell, and hollow nanoparticles) by capitalizing on a new class of unimolecular star-like block copolymers as nanoreactors. This strategy is effective and able to produce organic solvent-soluble and water-soluble monodisperse nanoparticles, including metallic, ferroelectric, magnetic, luminescent, semiconductor, and their core/shell nanoparticles, which represent a few examples of the kind of nanoparticles that can be produced using this technique. The applications of these functional nanocrystals in energy-related applications (i.e., solar cells and photocatalysis) will also be discussed.

Student Focused. Land Grant. Research University.

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Published by Department of Physics

Last Updated: Wednesday, January 21, 2015 3:42:52 PM