Associate Professor

Harry Bermudez
At the intersection of materials science and biotechnology, we exploit various forms of self-assembly towards achieving desirable properties of proteins, nucleic acids, and surfactants.
Harry Bermudez

Professor & Department Head

Alfred J Crosby
Guided by fundamental science, Professor Crosby and his research group takes inspiration from examples in nature, as well as ubiquitous yet complex materials such as fabric, to develop and exploit simple, creative, and novel design paradigms that will change the way scientists, engineers, and the general public use and understand materials.
Alfred J Crosby

Professor

Todd Emrick
Researching synthetic organic/polymer chemistry, functionalization of nanoscale and 2-D materials, aqueous polymer assembly and the preparation of polymer-based therapeutics.
Todd Emrick

Associate Professor

Samuel Gido
My research is focused on understanding how controlled polymer molecular architecture can be used to guide the self-assembly and processing of materials in order to create novel and useful structures on a morphological length scale (nanometers to microns).
Samuel Gido

Robert K. Barrett Professor

Steve Granick
Current research projects include active polymers, molecules in extreme environments, biological intelligence and memory of non-neural cells.
Steve Granick

Professor

Greg Grason
Our research explores the role of geometric frustration in soft matter and polymeric assemblies through the combined lens of condensed matter theory, statistical physics and differential geometry. In assemblies, frustration arises from interactions between molecular or particulate “building blocks” that favor geometrically incompatible patterns of order. Counterintuitively, frustration often leads to self-organized states that are more exquisitely structured, and more robustly controlled, than their canonical, unfrustrated counterparts.
Greg Grason

Professor

David Hoagland
Projects in the Hoagland group examine polymer structure and dynamics in these materials using a range of experimental methods. The typical goal is to understand the behaviors of individual polymer molecules, i.e., their average conformation, where and how they move, or how rapidly they deform/recover when challenged with an external force.
David Hoagland

Assistant Professor

Melody Morris
The Morris group will engineer sustainable macromolecular materials to enable next-generation biomaterials, nanoreactors, and membranes, via automated and high-throughput tool development combined with multiscale physical characterization. The longevity and stability of most synthetic polymers has proven to be a major bottleneck in creating a sustainable materials world.
Melody Morris

Wilmer D. Barrett Professor

Murugappan Muthukumar
My research group is engaged in understanding how macromolecules, both biological and synthetic, assume their sizes and shapes, organize into assemblies, and move around in crowded environments. We employ a combination of theoretical, computational, and experimental techniques to uncover the underlying mechanisms of macromolecular phenomena in Physical Biology and Polymer Physics.
Murugappan Muthukumar

Silvio O. Conte Distinguished Professor

Thomas Russell
We have been recently focusing on the role of chain architecture on the lateral ordering and minimizing the size scale of the microdomains to the single nanometer level. Our efforts on the interfacial activity of nanoparticles aim to achieve multi-length scale assemblies of nanoparticles are pioneering a platform for encapsulation and diffusion barriers.
Thomas Russell

Professor

Maria Santore
Discovering mechanisms for adhesion, lubrication, assembly, response, and reconfiguration in soft material systems, focusing on the dynamic interactions of polymers, biomolecules, nanoparticles, colloids, and cells. Coupling material interactions with flow and deformation to control structures and dynamics. Translating new interfacial mechanisms to the application-specific design of responsive / active interfacial materials
Maria Santore

Professor

Gregory Tew
Macromolecular research in this century will be defined by discoveries at the interface of chemistry, biology, and materials science. Research in the Tew group is focused on problems at this interface.
Gregory Tew

Professor

James Watkins
We develop, characterize and utilize nanoscale and hybrid materials for the fabrication of devices that exploit the unique properties of the materials that we create. Our approaches include direct imprint patterning of device structures using nanoparticle-based inks, additive driven self-assembly with brush block copolymers and other templates in which interactions among each of the components are designed to overcome barriers to creating well-ordered systems, materials chemistry through photothermal processing and the creation of large area nanostructured materials and devices through scalable manufacturing approaches, including roll-to-roll process platforms.
James Watkins