This course introduces the concepts of soft condensed matter and their use in understanding the mechanical properties, dynamic behavior, and self-assembly of living biological materials. We will take an engineering approach that emphasizes the application of fundamental physical concepts to a diverse set of problems taken from the literature, including mechanical properties of biopolymers and the cytoskeleton, directed and random molecular motion within cells, aggregation and collective movement of cells, and phase transitions and critical behavior in the self-assembly of lipid membranes and intracellular structures.

An introductory course on materials used civil and environmental engineering. Lectures on structure and properties of construction materials including concrete, steel, glass and timber; fracture mechanics; strength testing; mechanisms of deterioration; impact of material manufacturing on the environment. Labs on brittle fracture, heat treatment of steel, strength of concrete, mechanical properties of wood.

The course focuses on the linear and non-linear rheology of colloidal materials and materials processing and solidification mechanisms. The rheological sections of the course focus on the fundamentals of rheological properties, viscoelasticity, flow, and constitutive models. The materials processing sections focus on chemistry, physics, and mechanics principles governing the behavior of materials and particulate. The course objective is to teach a framework for quantitative analyses of materials' rheological responses and processes and help students understand materials' capabilities and limitations.

This course investigates the technology and underlying science of micro-and nano-fabrication, which are the methods used to build billions of electronic and optoelectronic devices on a chip, as well as general small sensors and actuators generally referred to as micro-electromechanical systems (MEMS). The general approach involves deposition, modification, and patterning of layers less than one-micrometer thick, hence the generic term "thin-film" processing. Topics covered: film deposition and growth via physical and chemical vapor deposition, photolithography, pattern transfer, plasma-processing, ion-implantation, and vacuum science.

This class will teach you about optical and photonic sensing technologies and their applications to environmental monitoring. The course will contain elements of atmospheric science and Earth observation, fundamentals of optics, photonics and laser physics, as well as a survey of modern optical and spectroscopic sensing applications. In this course students will be asked to prepare two oral presentations and there will be three laboratory assignments focused on fundamentals of optical sensing

An introductory course for the first and second year graduate students to understand the theory and application of the photonic materials and devices, which have feature size smaller than the wavelength of light, termed "subwavelength photonics (SWP) or "subwavelength optical elements" (SOE). The subwavelength materials/devices include dielectric and metallic (plasmonic) structures. Main topics covered: 1. rigorous Maxwell theory for SWPs, 2. mean-field theory for SWPs, 3. non-resonant SWPs, 4. resonant SWPs 5. applications of SWP devices and 6. numerical simulation.

This course investigates the technology and underlying science of micro-and nano-fabrication, which are the methods used to build billions of electronic and optoelectronic devices on a chip, as well as general small sensors and actuators generally referred to as micro-electromechanical systems (MEMS). The general approach involves deposition, modification, and patterning of layers less than one-micrometer thick, hence the generic term "thin-film" processing. Topics covered: film deposition and growth via physical and chemical vapor deposition, photolithography, pattern transfer, plasma-processing, ion-implantation, and vacuum science.

The course covers concepts related to the chemistry of inorganic and organic materials found in the pristine and contaminated settings in the Earth surface environments, with an introduction to the modern field sampling techniques and advanced laboratory analytical and imaging tools. Different materials characterization methods, such as optical, infrared, and synchrotron X-ray spectroscopy and microscopy, will also be introduced. Field sampling and analysis of materials from diverse soil and coastal marine environments will be the focus during the second half of the semester.

Minerals are the fundamental building blocks of the Earth. Their physical, chemical, and structural properties determine the nature of the Earth and they are the primary recorders of the past history of the Earth and other planets. This course will provide a survey of the properties of the major rock-forming minerals. Topics include crystallography, crystal chemistry, mineral thermodynamics and mineral occurrence. Emphasis will be on the role of minerals in understanding geological processes. Laboratories will focus on developing an understanding of crystallography, structure-property relationships, and modern analytical techniques.

Life finds a way, to quote Jurassic Park, and understanding how life does things can help us not only better understand it, but also better build, heal, and design our own living systems. This course focuses on the intersection of mechanics, materials science, and biology and focuses on two themes. (1) We use special engineering principles from different disciplines to understand how mechanics and material properties enable cells to make everything from beating hearts to velociraptors. (2) We apply this knowledge to learn how to design new biomedical devices and biomaterials while considering regulatory and bioethics guidelines.

In this course we present a survey of problems at the interface of biology, physics and engineering to discuss how nature invented many tiny sensors, machines and structures that are important for functions of cells and organisms. Using this knowledge, we comment how to engineer and self-assemble tiny devices with DNA origami, how to design thin structures that can transform into specific shapes in response to external stimulus, how to make structures with tunable surface properties (drag, adhesion, hydrophobicity/hydrophilicity), how to make flexible electronics, how to make metamaterials with unusual properties, etc.

An introduction to the structure and properties of important current and future materials, including metals, ceramics, semiconductors, polymers. Emphasis will be placed on the phase behavior, processing of materials, and how the structure of these materials affect their physical, mechanical, electrical and thermal properties.

This course covers foundational topics associated with the thermodynamics and kinetics of phase transformations in materials, with an eye towards applications in areas such as microelectronics & computing, advanced manufacturing, and energy storage. A combination of thermodynamics principles, mathematical modeling, and experimental observations are used to understand how materials transform between states with different physical and chemical properties.

This course examines methods for simulating matter at the atomistic scale with emphasis on the concepts that underline modern computational methodologies for classical many-body systems at or near statistical equilibrium. The course covers Monte Carlo and Molecular Dynamics (from basics to advanced techniques), and includes an introduction to ab-initio Molecular Dynamics and the use of Machine Learning techniques in molecular simulations.

A multidisciplinary course offering a practical introduction to techniques of imaging structure and compositional analysis of advanced materials. Focus on principles and applications of various characterization methods. Covered topics include AFM, SEM, TEM, XRD, EDX/WDX, EELS, Raman, Ellipsometry, Confocal Microscopy, sample preparation and image processing, etc. Hands-on experience is emphasized.

Composites, porous media, foams, colloids, geological media, and biological media are all examples of heterogeneous materials. The relationship between the macroscopic (transport, mechanical, electromagnetic, and chemical) properties and material microstructure is formulated. Topics include statistical characterization of the microstructure; percolation theory; fractals; sphere packings; Monte Carlo techniques; image analysis; homogenization theory; cluster and perturbation expansions; variational bounding techniques; topology optimization methods; and cross-property relations. Biological and cosmological applications are discussed.

This class addresses the practical aspects, theory, implementation and utilization of optimization in conjunction with analysis tools. It aims to acquaint the student with the state-of-the-art optimization techniques and their application to engineering problems. Besides traditional methods, it introduces the modern and powerful topology optimization method together with its application to material and structural systems. In this context, it also introduces rapid prototyping and 3D/4D printing techniques at different scales.

This is a one-semester course in advanced quantum mechanics, and counts as a "core course" in the physics graduate program. The emphasis is on topics relevant to quantum information, quantum computation, entanglement, and many-body quantum dynamics.

Course introduces and presents ongoing theoretical investigations of new research topics in condensed matter physics: topological insulators and Chern numbers, topological superconductors, the fractional quantum Hall effect and non-abelian statistics, flat-band systems, spin liquids. The techniques needed to deal with such systems, such as Chern numbers, topological band theory, Berry phases, conformal field theory, Chern-Simons theory, t-J models, Gutzwiller wavefunctions, Hubbard models, are explained.