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4434Molecular reaction dynamics
http://www.merlot.org/merlot/viewMaterial.htm?id=490974
This package, written in 1998, includes interactive questions and demonstrations on the dynamics of chemical reactions. The aim is to show the effect of the potential energy surface, on reaction rates. It is intended for third or fourth year undergraduates in Chemistry. To download, click on View Download and follow the instructions. To uninstall, use the standard Windows option of "Add or Remove Programs״.10.626 Electrochemical Energy Systems (MIT)
http://www.merlot.org/merlot/viewMaterial.htm?id=883965
10.626 introduces principles and mathematical models of electrochemical energy conversion and storage. Students study equivalent circuits, thermodynamics, reaction kinetics, transport phenomena, electrostatics, porous media, and phase transformations. In addition, this course includes applications to batteries, fuel cells, supercapacitors, and electrokinetics.12.141 Electron Microprobe Analysis (MIT)
http://www.merlot.org/merlot/viewMaterial.htm?id=884505
The electron microprobe provides a complete micrometer-scale quantitative chemical analysis of inorganic solids. The method is nondestructive and utilizes characteristic X-rays excited by an electron beam incident on a flat surface of the sample. This course provides an introduction to the theory of X-ray microanalysis through wavelength and energy dispersive spectrometry (WDS and EDS), ZAF matrix correction procedures and scanning electron imaging with back-scattered electron (BSE), secondary electron (SE), X-ray using WDS or EDS (elemental mapping), and cathodoluminescence (CL). Lab sessions involve hands-on use of the JEOL JXA-8200 Superprobe.5.72 Statistical Mechanics (MIT)
http://www.merlot.org/merlot/viewMaterial.htm?id=884061
This course discusses the principles and methods of statistical mechanics. Topics covered include classical and quantum statistics, grand ensembles, fluctuations, molecular distribution functions, other concepts in equilibrium statistical mechanics, and topics in thermodynamics and statistical mechanics of irreversible processes.6.701 Introduction to Nanoelectronics (MIT)
http://www.merlot.org/merlot/viewMaterial.htm?id=884231
Traditionally, progress in electronics has been driven by miniaturization. But as electronic devices approach the molecular scale, classical models for device behavior must be abandoned. To prepare for the next generation of electronic devices, this class teaches the theory of current, voltage and resistance from atoms up. To describe electrons at the nanoscale, we will begin with an introduction to the principles of quantum mechanics, including quantization, the wave-particle duality, wavefunctions and Schrödinger's equation. Then we will consider the electronic properties of molecules, carbon nanotubes and crystals, including energy band formation and the origin of metals, insulators and semiconductors. Electron conduction will be taught beginning with ballistic transport and concluding with a derivation of Ohm's law. We will then compare ballistic to bulk MOSFETs. The class will conclude with a discussion of possible fundamental limits to computation.Physical Chemistry
http://www.merlot.org/merlot/viewMaterial.htm?id=433020
This online textbook/course is designed to incorporate various topics from the overall site, ChemWiki. The ChemWiki is “designed to maintain all Modules (pages of chemistry information) in the primary sections” for the core classes in Chemistry. There is also a link to Wikitexts, which contains classes put together by faculty who select which modules to include. As with any wiki, the materials are continually being updated, but in reviewed by peers. "Physical Chemistry is the application of physical principles and measurements to understand the properties of matter, as well as for the development of new technologies for the environment, energy and medicine. Advanced Physical Chemistry topics include different spectroscopic methods (Raman, ultrafast and mass spectroscopy, nuclear magnetic and electron paramagnetic resonance, x-ray absorption and atomic force microscopy) as well as theoretical and computational tools to provide atomic-level understanding for applications such as: nanodevices for bio-detection and receptors, interfacial chemistry of catalysis and implants, electron and proton transfer, protein function, photosynthesis and airborne particles in the atmosphere.״