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Introduction of Nanoplasmonics 2011 Spring Semester.

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Presentation on theme: "Introduction of Nanoplasmonics 2011 Spring Semester."— Presentation transcript:

1 Introduction of Nanoplasmonics 2011 Spring Semester

2 What we are going to deal with Metallic Nanoparticle or 2-D Nanostructure Metallic Thin Film and Light!!!

3 Examples of Metallic Nanoparticles (Standalone)

4 Examples of Metallic Nanostructures (2D)

5 What if the size of metallic particle is down to nanoscale? Surface Plasmon Resonance, Photothermal Effect and Strong field enhancement

6 Surface Plasmon Resonance White light Excitation Group oscillation of electron cloud Noble metal nano-structure Extinction Resonance Frequency f Displacement Resonance Frequency k c m F(t) = x

7 W. A. Murray, W. L. Barnes, Adv. Mat. (2007) Multi wavelength excitation Extinction Selective Re-radiation (i.e. Scattering) Material, Size, and Shape Dependent Optical Antenna!!! Selective Target releasing by noble nanoparticles

8 http://www.youtube.com/watch?v=pRzlzgA LvqQ&feature=relatedhttp://www.youtube.com/watch?v=pRzlzgA LvqQ&feature=related Surface Plasmon Resonance in Metallic Thin Film

9 Applications of plasmonic photothermal conversion Laser-induced size-reduction of metallic nanoparticles Control of gene regulation or protein expression in cell Targeted local thermotherapy of cancer Local drug delivery by optical switch Optically driven collective oscillation of electrons Plain Nanosphere Nanocrescent Collision of electrons with lattice: Phonon relaxation Excitation of molecular vibrations in ambience E ,  T   T < 10 K or Require local high power/pulsed lasers Direct conversion of optical energy into heat Photothermal Conversion

10 Strong Field Enhancement Conventional Lens Focusing Focused Spot d ~ * * : Wavelength Plasmonic Lens Focusing Target molecules Lens >> /nm Intensity (A.U.) Molecular Fingerprint Highly focused EM field High Sensitivity Spatial Resolution

11 Stained Glass & Roman Cup

12 Applications of Nanoplasmonics From Catalysis to Biology

13 Applications of plasmonic photothermal conversion Laser-induced size-reduction of metallic nanoparticles Control of gene regulation or protein expression in cell Targeted local thermotherapy of cancer Local drug delivery by optical switch Optically driven collective oscillation of electrons Plain Nanosphere Nanocrescent Collision of electrons with lattice: Phonon relaxation Excitation of molecular vibrations in ambience E ,  T   T < 10 K or Require local high power/pulsed lasers Direct conversion of optical energy into heat Photothermal Conversion

14 http://www.youtube.com/watch?v= 3J9aUQSK_QE Video Clip for Photothermal Effect

15 Photothermal Therapy

16 ONCOS * Molecular Therapeutics: Example ONCOS

17 Strong Field Enhancement Conventional Lens Focusing Focused Spot d ~ * * : Wavelength Plasmonic Lens Focusing Target molecules Lens >> /nm Intensity (A.U.) Molecular Fingerprint Highly focused EM field High Sensitivity Spatial Resolution

18 Excitation Raman Scattering Good: Molecular fingerprint signatures Label-free detection Bad: Signal too weak Molecule Raman Scattering *SERS: Surface-enhanced Raman Scattering SERS Metallic Nanostructure Adsorbed Molecule Excitation Raman Scattering Field Enhancement Improving Raman scattering by double field enhancement Raman Signal Enhancement  Local Field Enhancement  4 Raman molecular fingerprint spectrum Single Molecule Detection by SERS*

19 Last Video Clip for This Hour http://www.multimedia.ethz.ch/episo de_play/?doi=10.3930/ETHZ/AV- 9b0a8bfb-a42e-49c1-8237- bbd643ddc7a8

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