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Welkom to COSMOS!

Welkom to COSMOS!. The World of Molecules. Chemistry at the Nano-scale. COSMOS UCI, summer 2008. hour. Monday. Tuesday. Wednesday. Thursday. Friday. Saturday. Sunday. 7- 8:30. breakfast. breakfast. breakfast. breakfast. breakfast. 9:00- 10:15. Lecture 1. Lecture 1. Lecture 1.

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Welkom to COSMOS!

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  1. Welkom to COSMOS! The World of Molecules Chemistry at the Nano-scale COSMOS UCI, summer 2008

  2. hour Monday Tuesday Wednesday Thursday Friday Saturday Sunday 7- 8:30 breakfast breakfast breakfast breakfast breakfast 9:00- 10:15 Lecture 1 Lecture 1 Lecture 1 Lab/field Lab/field 10:30- 11:15 Lecture 2 Lecture 2 Lecture 2 lunch lunch lunch lunch lunch 1:15- 2:30 Sci. Comm Sci. Comm Sci. Comm Lab/field Lab/field 3:00- 5:00 Special Special Special Project Project 5:00- 6:30 dinner dinner dinner dinner dinner Structure

  3. groups • Group 1 Group 2 Group 3 • John Chu Kathleen Kang Eugene Pynko Tatyana Dynikova Steven Kezian Adarsh Ramakrishnan Seo-Im Hong Darren Pan Jennifer Stukenberg Jiwoo Jeon Megan Stone Diane Tran • Group 4 Group 5 • Eugene Shin Justin Wang • Michael Vorobyov Yutong Wu • Kimberly Vu Ringo Yen • Elizabeth Wille

  4. Instructors Prof. Nien-Hui Ge 2D IR spectroscopy When Atoms Meet Understanding the Covalent Bond Bonding in Solids

  5. Instructors Prof. Ara Apkarian Ultrafast Molecular Spectroscopy Lasers Pulses of Light Fast Photography

  6. Instructors Prof. Wilson Ho Scanning Tunneling Microscopy Seeing Single Molecules Lasers and Microscopes

  7. Instructors Prof. Phillip Collins Nanoscopic Devices More than One, less than a Mole Access to the Nanoworld Nanoscience vs. Nanotechnology

  8. Lab sessions Min Kim Lab 1: Infrared Fourier Transform Spectroscopy Shawn Perdue Lab 2: The Nature of Light Max Zimmerley Lab 3: Two-photon Microscopic Imaging Danny Wan Lab 4: Imaging at the Nanoscale Wendong Xing Lab 5: Millikan Oil Drop Experiment

  9. What is matter?

  10. Zooming in

  11. Zooming in

  12. Zooming in

  13. Zooming in

  14. The world is made of molecules

  15. Molecules are made of atoms

  16. Atom

  17. Atoms are real Sodium chloride crystal lattice

  18. 10 million times 10 million times 0.5 mm (5 x 10-4 m) ~ 1/50 ” 50 pm (5 x 10-11 m) ~10 cm 13 x 105 m ~ 8 x 103 mi Atoms are small

  19. Atoms have tiny masses Proton (charge 1+): mp = 1.672 x 10-27 kg Neutron (charge 0): mn = 1.674 x 10-27 kg Electron (charge 1-): me = 9.109 x 10-31 kg

  20. There is an attractive force between the electron and the nucleus Why the Atom stays together + r - Coulomb potential

  21. The World of Atoms Atoms are extremely small Protons, neutrons and electrons are extremely light Electrons are confined to the vicinity of the nucleus How do electrons move around the atom?

  22. Sir Isaac Newton(1642-1727) What Newton predicts Motion of object can be precisely calculated from a set of observables: x - position of object v - velocity of object E - energy of object

  23. Erwin Schrödinger(1887-1961) Small particles behave like waves! What Schrödinger says Position, v and E of very small object can not have any random value. Observables have only certain discrete values

  24. Who’s right? White light passing through a prism produces a continuous spectrum. Hydrogen gas exposed to an electric discharge gives a line spectrum.

  25. Who’s right? Electrons are particles with a rest mass of me = 9.109 x 10-31 kg Do they also behave like waves? Looks like the pattern that a wave would make!

  26. Who’s right? Electrons confined to a circular well

  27. Schrödinger Newton: 2nd prize Schrödinger wins first prize! Electrons, protons, atoms have wave-like properties The world of atoms is described through Quantum Mechanics

  28. x v, E etc. x, v, E etc. Math tools Newton: Quantum: The shape of the wavefunction can be obtained from the Schrödinger equation:

  29. + - r Wave properties The electron bound to the atom looks like a standing wave.

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