Nanoscience Course Offerings

CHEM 1700 Nanoscale Materials: Synthesis and Applications

ENGN2911 / BIOL2840  Small Wonders – the Science, Technology, and Environmental Health Impacts of New Nanomaterials

CSCI 2570 Introduction to Nanocomputing

ENGN 1930B  Biophotonics

ENGN 2630 - Electro-Optical Properties of Materials and Biomolecules

ENGN 2910F - Nano and Micro Mechanics of Solid Interfaces

ENGN 2910J - Mechanics and Surface Science of Nanostructures

PHYS 0120 Adventures in Nanoworld (freshman seminar)

ENGN 2630 - Electro-Optical Properties of Materials and Biomolecules

ENGN 2910O - Molecular Simulation Methods in Mechanics and Physics

ENGN 2910P - Nano-system Design

ENGN 2911A - Nanoelectronics

ENGN 2911E - New Frontiers of Solid Mechanics in Nano- and Bio- Research

CSCI 2560 - Applied Theory of Computation

ENGN 2911K - Biological Impacts of Nanomaterials

ENGN 2912A - Toxicity of Nanoparticles

ENGN 237A Mechanics and surface science of thin films and nanostructures

More Information...

ENGN 2910Z Small Wonders: The Science, Technology, and Human Health Impacts of Nanomaterials

Instructors:            
Robert Hurt, Division of Engineering
Agnes Kane, Department of Pathology and Laboratory Medicine

Survey course focusing on nanomaterials as enabling components in emerging nanotechnologies. Covers scaling laws for physicochemical properties, synthesis routes, manipulation and characterization tools, and example applications in sensors, composites, advanced energy devices, and nanomedicine. Impacts of nanomaterials on environment and health, including the interactions between nanoscale structures and biological molecules, cells, and whole organisms. Undergraduate enrollment by permission

CHEM 1700 Nanoscale Materials: Synthesis and Applications

Instructor:   Shouheng Sun, Department of Chemistry

An introduction to the chemical principles in the synthesis and self-assembly and physical properties in nano-optics, nano-electronics, nano-magnetism and nano-catalysis of nano-particles, nano-rods, nano-tubes, nano-wires and porous nano-structures. It will further illustrate how these nano-materials and their assemblies can be used in information storage, catalysis and biomedicine.

CSCI 2570 Introduction to Nanocomputing

INSTRUCTOR: John Savage – Department of Computer Science

Nanoscale technologies employing materials whose smallest dimension is on the order of a few nanometers are expected to replace lithography in the design of chips. We give an introduction to computational nanotechnologies and explore problems presented by their stochastic.

COURSE WEBSITE: http://www.cs.brown.edu/courses/cs257/

Adventures in Nanoworld (PHYS0120)

Instructor: Professor Dmitri Feldman
Department of Physics
Dmitri_Feldman@brown.edu

EN291S010: Nanosystem Design

Professor Iris Bahar
Email: Iris_Bahar@Brown.edu

Course Announcement

• Over the past few decades, computer system performance has been driven by improvements in silicon fabrication technology. However, within the foreseeable future, improvements in conventional fabrication will be limited by basic physics, as devices become small enough that the bulk assumptions used in analyzing their performance become incorrect. A number of promising candidates for new basic technologies have been demonstrated in the lab, including single-molecule organic switches and nanotube electron conduits. This course will focus on considering how these new basic devices will impact VLSI, computer architecture, and how we may design systems to take advantage of the opportunities they offer. The goal of this course is to provide a broad understanding of the many fields that are involved in electronic
  nanotechnology.

• Class will include a mix of lectures and discussion on assigned reading of recent publications. Students will be responsible for leading and participating in these discussions. A course project will also be required. Prerequisites: EN164 and EN160 are helpful, but not required.

• Graduate or upper-level undergraduate students are welcome.

Biological Impacts of Nanomaterials (EN 292)

Instructor: Prof. T. J. Webster
Barus and Holley Room 160
e-mail: Thomas_Webster@brown.edu
phone: 3-2318 (preferred contact by e-mail)

Course Description:
This course will emphasize advancements nanomaterials have made in several fields. In doing so, this course will cover fundamentals of nanomaterial synthesis and biological responses of nanomaterials if ingested, inhaled, or implanted. Biological concepts (immune response, cellular toxicity, etc.) will be combined with engineering concepts (manufacturing and property control) to understand the relationship between manufacturing and biological impacts of nanomaterials.

ENGN 237A
Mechanics and surface science of thin films and nanostructures

Prof. Vivek Shenoy
Tue,Thu – 9:00-10:20, BH 245
Main Topics:

1. Atomic Structure of semiconductor and metal surfaces
2. Models for growth and evolution of surface based nanostructures
3. Instabilities in thin film and crystal growth
4. Strain driven self-assembly
5. Surface morphology and composition
6. Defect formation in nanostructures

left to right:
Stress domains on Si(111)
Ge quantum dots on Si(001) 
Atomic structure of Si(001)

ENGN 292 Special Topics:Nanoelectronics

INSTRUCTOR: Roderic R. Beresford – Division of Engineering

Review and analysis of novel and exotic electronic devices, and proposals for extending scaling into the nanometer regime.  Contemporary research and development in areas such as nonclassical CMOS; single-electron and nanocrystal memories; 1D nanotube and nanowire transistors, qubits, quantum dots, spin transistors, molecular electronics; and the realization of such elements in arrays and biologically inspired networks.  A unifying theme is the understanding of the fundamental limits to scaling of devices that employ electric charge as the state variable, and the problems involved in extending nanoelectronics to harness other state variables, such as the spin.    

Toxicity of Nanoparticles EN 291

Instructor:    Prof. T. J. Webster
Barus and Holley Room 224
e-mail: Thomas_Webster@brown.edu
phone: 3-2318 (preferred contact by e-mail)

Course Description:
This course will emphasize advancements nanoparticles have made in several medical fields such as preventing, diagnosing, and treating various diseases. This course will integrate fundamental knowledge of toxicity into such applications. In particular, the course will cover current results in terms of nanoparticle applications and potential toxicity. Toxicity in such organs as the lungs, blood, kidneys, liver, etc. will be emphasized. Biological concepts will be combined with engineering concepts to understand the relationship between manufacturing and nanoparticle toxicity.