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Registration Form Registration Form understanding of the fundamental science underlying field. The solution to this problem has important L8: Model building: 2. Multilayer structures for U.S. professors, postdocs, and graduate students molecular structures and its applications to artificial implications in micro/nano fluidic devices for multifunctionality: from OLEDs to catalysts to bioactive (See other side for NSF Fellowships). manipulation of molecules in order to achieve specific bioengineering and medical applications. By using unique films (Dr. Ellis) Name: _____________________________ functions with high efficiency. Upon the completion of multiscale simulation tools, the handling of various nano- L9: Model building: 3. Design of a robust solid oxide Title: ______________________________ such functional materials at the molecular level, the /bio- materials is mainly discussed with future prospects. electrolyte (Dr. Ellis) Address: ___________________________ interface from nanoscale to micro- and macro- scale should The interface between nanomaterials and micro- or macro- ___________________________________ be provided to lead the novel nanomaterials to a real scale devices requires intermediate nanostructures as a Tue 1:00-4:00 City: ________________State: _________ marketplace. platform, which is achieved by nanomanufacturing steps. L10: Modeling: Electrokinetic assembly and manipulation Zip Code: ________Country: __________ Nanoscale fabrication methods will be discussed by (Dr. Liu) E-mail: ___________________________ This short course will cover topics from atomic-level Professor Jae-Hyun Chung. Top-down methods in L11: Application to biomaterials (Dr. Liu) Affiliation (will be printed on your name tag) handling to molecular level manufacturing and, ultimately nanoscale science are reviewed with recently developed L12: Application to cell dynamics (Dr. Liu) ___________________________________ to final applications. Major research and development in nanomanufacturing methods. On the other hand, bottom-up Phone: (___)_________________________ nanotechnology will be reviewed through the talks. approaches assembling nanomaterials are introduced with Wed 9:00-12:00 Professor Mark Hersam will discuss atomic level new directions to designing nanoscale devices. L13: Introduction to thin film processing (Dr. Barnett) Institute Mission manipulation by scanning probe microscopy. High L14: Thin film nucleation and structure (Dr. Barnett) • To identify and promote important areas of resolution lithography can lead to modification of surface As future applications, micro/nanofluidic devices will be L15: Properties of thin films (Dr. Barnett) nanotechnology, and to create new areas of focus properties at the atomic level, which potentially benefit discussed with critical challenges by Professor Arun which will augment current nanotechnology research storage devices of extremely high density. Professor Majumdar. The scaling issues in energy production and Wed 1:00-4:00pm and development by universities, industries and Hersam will also provide an introduction to the properties fluids and heat transfer are discussed with emphasis on L16: Top-down vs. Bottom-up approaches (Dr. Chung) government. and processing of carbon nanotubes. In particular, a nanoscale fluidic phenomena and devices. These are L17: Nanomanufacturing (Top-down) (Dr. Chung) • To train future and practicing engineers, scientists and scalable and industrially viable strategy for producing relevant for processes such as energy-efficient separation of L18: Nanomanufacturing (Bottom-up) (Dr. Chung) educators in the emerging areas of nanotechnology, monodisperse carbon nanotubes that was recently invented fuels. Nanoscale fluidic phenomena are also relevant for nano-engineering, nano-mechanics, and nano- in the Hersam Laboratory will be featured. As a energy storage devices such as batteries. Furthermore, Thu 9:00-12:00 materials. fundamental building block toward multi-functional nanofluidics is important in analyzing and processing L19: Scaling issues in micro/nanofluidics and their • To exchange new ideas, disseminate knowledge and materials, nanoscale porous materials are discussed by biological molecules. Nanoscale heat and charge transport applications (Dr. Majumdar) provide valuable networking opportunities for Professor Don Ellis. The materials can be used for selective are important in many energy applications such as L20: Heat transport in nanoscales (Dr. Majumdar) researchers and leaders in the field. separation of molecules and molecular sensors. thermoelectric refrigeration and power generation. A L21: Applications in thermoelectric energy conversion (Dr. Requirements for regulation of mass and charge transport at fundamental understanding of how chemical bonding and Majumdar) Course Description the ion/electron level, in gas phase, and for molecular nanostructures influence transport is critical for these Modern technological society is increasingly concerned separations, catalysis, and sensing provide a set of applications. Professor Majumdar will introduce the Thu 1:00-4:00 with high performance materials, and in achieving good 'chemical criteria' for design. Requirements for device subject from macroscopic concepts and then highlight the L22: Introduction to solid oxide fuel cells (Dr. Barnett) efficiency in energy conversion, communications, stability and useful operational lifetime will impose differences in both science and engineering at the L23: Solid oxide fuel cell nano- and micro-structure effects computation, and chemical processing. This is evidenced by possibly conflicting 'physical criteria.' Another important micro/nanoscales. (Dr. Barnett) the high demand of microelectronics, and they have become method for producing nano-scale structures is via thin film L24: Fuel cell modeling (Drs. Ellis and Liu) an integral part of our lives nowadays – computers, cell deposition. These can be in the form of nano-layered Program Outline phones, iPods, automobiles, aerospace systems, and structures or self-assembled three dimensional structures. L: (lecture) Course Credit and Pre-requisites biomedical systems all consist of these ever-shrinking Professor Barnett will introduce the basics of thin film Mon 9:00-12:00 The total number of contact hours for the four-day program microelectronics. The advances in microelectronics deposition methods, nucleation and structure, and L1: Introduction to lithography (Dr. Hersam) is 24, and 2.4 CEUs. There are certain pre-requisites for technologies have brought and will continue to bring properties. Properties to be discussed will include L2: Scanning probe microscopy (Dr. Hersam) each topic. In order to maximize the learning experience, convenience to our daily lives, enhance health and safety, mechanical, electrical, and electrochemical, the latter L3: Scanning probe lithography (Dr. Hersam) we will provide complete course materials to students prior and help to make major scientific discoveries among many relevant to thin and thick films in solid oxide fuel cells. to the class. Pre-requisite material will be reviewed briefly other advantages. The market demand for and applications Mon 1:00-4:00pm at the beginning of each course. of microelectronics are expanding rapidly ranging from Upon the synthesis of novel materials, the L4: Introduction to carbon nanotubes (Dr. Hersam) consumer electronics to industry, homeland security, characterization and manipulation of such materials with L5: Advanced processing of carbon nanotubes (Dr. Instructors medical science, aerospace applications and so on, making high accuracy will be a major challenge. This will be Hersam) great synergy with the existing technology. addressed by Professor Wing Kam Liu with modeling and L6: General principles of simulation: (Dr. Ellis) Dr. Scott A. Barnett is a Professor in the Materials Science and simulation using the newly developed Immersed Coupling of first-principles theory, experimental data, and Engineering department at Northwestern University. He is also In the last decade, various aspects of nanotechnology Electrokinetic Finite Element Method (IEFEM) coupled simplified parameterized models founder of Functional Coating Technology LLC. After receiving have been actively investigated to achieve specific goals in with multiscale physics to treat a complex multi-body his Ph.D. in Metallurgy from the University of Illinois at Urbana- materials, medicine, electronics, and energy production. By interaction problem that contains deformable objects, ions, Tue 9:00-12:00 Champaign in 1982, he held postdoctoral appointments at the University of Illinois and Linkoping University (Sweden). He took dexterous manipulation of molecules, innovative concepts and fluids. The ions in the aforementioned problem L7: Model building: 1. Macromolecular filters and complicate the situation by affecting the flow regime and nanoreactors (Dr. Ellis) his present position at Northwestern in 1986. His research focuses of materials and devices have been proposed and on thin films and coatings produced by ion-assisted deposition, developed. Such molecular manufacturing requires rigorous distribution of the charges upon imposing an electric physical vapor deposition, and colloidal deposition methods. His materials focus is on nano-layered nitride hard coatings, transparent in Electrical Engineering. Besides his educational training, Dr. NSF Fellowships conducting oxide thin films, and solid oxide fuel cells. Dr. Barnett Hersam has also been employed by Argonne National Laboratory
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