大发彩票平台

大发彩票平台.CA / Department of Chemistry / Faculty

Matthew J. Harrington

大发彩票平台

Professor

CRC tier 2 in Green Chemistry
Co-Director of 大发彩票平台 Institute for Advance Materials (MIAM)
B.A. (University of Delaware, 2002)
Ph.D. (University of California, Santa Barbara, 2008)
Postdoctoral Fellow (Max Planck Institute of Colloids and Interfaces, 2008-2010)
Alexander von Humboldt Fellowships for Postdoctoral Researchers
Research Group Leader (Max Planck Institute of Colloids and Interfaces, 2010-2017)
Associate Faculty Member of the International Max Planck Research School on Multi-scale Biosystems (Max Planck Institute of Colloids and Interfaces, 2016-2017)

Contact Information

Office: Pulp & Paper 106
Phone: (514) 398-3180
Email: matt.harrington [at] mcgill.ca
Group Website:

Research Themes:

  • Chemical Biology
  • Materials Chemistry

Research Interests

Green Materials Fabrication Inspired by Nature

Living organisms rapidly fabricate a range of high performance biopolymeric materials such as silk and mussel byssus from biomolecular building blocks (e.g. proteins) via bottom-up assembly processes. Our group is fascinated by how characteristic chemical features of these building blocks and their multi-scale structural organization determine the emergent properties of biogenic materials and by the processes by which these materials are fabricated. Moreover, we are interested in adapting and translating the extracted natural design principles for production of new synthetic materials exhibiting complex multi-scale structure and advanced material properties (e.g. self-healing, stimuli-responsive behavior).

Thus, our main research goals are to:

  1. Elucidate biogenic structure-function relationships and bio-fabrication processes.
  2. Adapt natural design principles for development of advanced bio-inspired materials.

To achieve these goals, our group utilizes a cross-disciplinary strategy comprised of approaches in materials science, biochemistry, molecular biology and polymer science. In particular, we aim to couple advanced materials characterization techniques (e.g. confocal Raman microspectroscopy and X-ray diffraction) with in situ mechanical testing and bio-fabrication investigations in order to connect the multi-scale structural organization and chemistry of protein building blocks with the bulk material properties.聽

Currently Teaching

CHEM 334. Advanced Materials.

Note: For information about Fall 2025 and Winter 2026 course offerings, please check back on May 8, 2025. Until then, the "Terms offered" field will appear blank for most courses while the class schedule is being finalized.

Credits: 3
Offered by: Chemistry (Faculty of Science)
This course is not offered this catalogue year.

Description

Survey of the physical and chemical structure-function relationships defining advanced materials, including an introduction to basic materials science and characterization. Topics include supramolecular polymers, self-healing materials, advanced surfaces and adhesives, bio-inspired materials, shape memory materials, sensors and actuators, and photonic materials.
  • Restriction: Not open to students who have taken or are taking PHYS 334.
  • Restriction: Not open to students who have taken or are taking PHYS 334.
  • Fall
  • Prerequisites: CHEM 110/CHEM 120 and PHYS101/PHYS 102 or PHYS 131/PHYS 142, or CEGEP Physics and Chemistry, or equivalent. Prerequisite or Corequisite: one of CHEM 203, CHEM 204, CHEM 213 and CHEM 273, or equivalent; or one of PHYS 230 and PHYS 232, or equivalent; or permission of the instructor.

Most students use Visual Schedule Builder (VSB) to organize their schedules. VSB helps you plan class schedules, travel time, and more.

Back to top