1. Introducing concepts of nanoscience and nanotechnology for engineering education Sandra M. Mendoza Universidad Tecnológica Nacional – Facultad Regional Reconquista Consejo Federal de Investigaciones Científicas y Técnicas.

2. Outline  Introduction  The challenge  Objectives of the course  Audience  Course content  Didactical strategies and resources  Conclusions

3. Nanoscience Nanoscience is the study of matter in the nanometer range. Nanotechnology Nanotechnology comprises the set of techniques developed for the study, manipulation and control of matter in the same range with applications in the real world. Introduction

4. Position of nanoscience and nanotechnology topics over a base map of science. Each node is one of 175 subject categories in the SCI database, and the size of the node is proportional to the number of papers published in each. http://gtresearchnews.gatech.edu/mapping-nanotechnology/ Nano-related research has strong multidisciplinary roots Introduction

5. The challenge Engineering education

6. Complementing the engineering formal education in the field of advanced materials and nanotechnology, from a practical and applied point of view.  Selecting and applying the scientific knowledge in order to find solution for technological problems.  Understanding the scientific ‘nano-language’ to enhance the communication between researchers, engineers and society, i.e. to be the link between science and solutions in this field of fast development.  Getting constantly updated, with regards to new trends in advanced materials.  Learning about intellectual property, form scientific publications to patents and technology transfer. Objectives of the courseEngineering Scientific basic knowledge Applications

7. Complete basic university education in mathematics (calculus, arithmetic and analytical geometry), physics, chemistry, thermodynamic and statistics. Careers such as materials, nuclear or chemical engineering. But also mechanical, electrical, biological and civil engineering can be enriched by the course. Audience Undergraduate students

8.  Ultra high vacuum (UHV) technology  Solid state physics for engineering  Surface science and thin films  Molecular devices and machines  Sample characterization Microscopy techniques Spectroscopy techniques Miscellaneous Course content

9. Ultra high vacuum (UHV) technology  Vacuum operational ranges.  Vacuum pumps and functioning principles (ionic, sublimation, diffusion, rotary, and more).  Benefits and requirements.  Operational methods.  Applications.

10. Solid state physics for engineering  Crystalline (surface) structure.  Size-depending properties. Energy bands.  Nanoparticles.  Quantum dots.

11. Thin film solar panel Thin-Film Batteries for Direct Integration into Electronic Devices Surface science and thin films  Monolayers. Multilayers.  Physical vapour deposition (PVD).  Chemical vapour deposition (CVP).  Self-assembly.  Langmuir-blodget technique.  Electron/ion sputtering. Depth profiling.  Some case studies: graphene, alcanothiols, single and multiple walled carbon nanotubes (SWCNT and MWCNT), other fullerenes  Current and prospective applications. Surface science and thin films

12. Molecular devices and machines Encapsulation technology and controlled release  Supramolecular chemistry for engineers.  Functional molecules, nanodevices a nd nanomachines.  Electronic devices, MEMS, NEMS.  Photonic materials.  Introduction to nanoengineered materials.  New trends in material science. microelectromechanical systems chip Graphene and fullerenes

13. Sample characterization STM Image showing graphite (HOPG) atoms Synchrotron Soleil (France)  Microscopy probe techniques : STM), AFM, SEM, TEM.  Spectroscopy techniques: Synchrotron sources, XPS, AES, FT-IR, Raman spectroscopy. Electron energy loss spectroscopy (EELS and HREELS).  Miscellaneous: Surface selective diffraction techniques. Low energy electron diffraction (LEED). Contact angle. Break junction. Theoretical simulation methods. XPS spectrum of gold subtrate

14. The course must be in line with the curricular design, norms and rules of the university career where it will be incorporated.  Lectures, by experts in the field.  Experimental sessions where the student will be able to see, apply and get familiar with advanced technology available in material science centers and laboratories, as well as high-tech industries.  Testimonies of professionals who are active in the field Methodology: didactical strategies and resources

15. The list of didactical materials includes:  A selection of text books and a specially edited syllabus  Complementary texts.  Access to international publications and patents  Guides for experimental sessions  Authorized simulation software  Laboratory facilities  Online-conference facilities, in order to enrich lectures and laboratory tutorials with the expertise of professionals, who are geographically distant from the course location.  PC, projector, blackboard/whiteboard. Methodology: didactical strategies and resources

16.  Nanoscience and Nanotechnology are emerging disciplines of science and technology that integrate a broad range of topics.  New engeneering challenges Alternative tool to provide solutions  Disciplines usually not included in formal engineering education (undergradue level)  Curriculum proposal advocated to complement formal education of engineering careers in the field of nanoscience and nanotechnology.  Impact on future engineers Skills for solving technological problems making use of nanotechnology Conclusions

17.  Universidad Tecnológica Nacional – Facultad Regional Reconquista  Consejo Federal de Investigaciones Científicas y Técnicas (CONICET)  WEEF Comettee Acknowledgments

18. Thank you

20. State of the art The first nanoengineering program in the world was started at the University of Toronto within the Engineering Science program as one of the Options of study in the final years. In 2003, the Lund Institute of Technology started a program in Nanoengineering. In 2004, the College of Nanoscale Science and Engineering(CNSE) was established on the campus of the University at Albany. In 2005, the University of Waterloo established a unique program which offers a full degree in Nanotechnology Engineering. Louisiana Tech University started the first program in the U.S. in 2005. In 2006 the University of Duisburg- Essen started a Bachelor and a Master program NanoEngineering. The University of California, San Diego followed shortly thereafter in 2007 with its own department of Nanoengineering. In 2009, the University of Toronto began offering all Options of study in Engineering Science as degrees, bringing the second nanoengineering degree to Canada. DTU Nanotech - the Department of Micro- and Nanotechnology - is a department at the Technical University of Denmark established in 1990.