Illinois iOptics Lecture 4: Advance applications in Nanomaterials, Photovoltaics, Organic/Inorganic Sensors, Materials Science, and Alternative Energies, etc. using Raman and Photoluminescence Technologies

10 Aug 2010 | Online Presentations | Contributor(s): Emmanuel Leroy, Michael Oweimrin

Emmanuel Leroy originally began his career at the Horiba Jobin Yvon facility in France (formerly Dilor) and moved to the USA as a Service Engineer to support the Raman products in North and South …

http://nanohub.org/resources/8961

Illinois iOptics Seminar Series

17 May 2010 | Series | Contributor(s): Gabriel Popescu, Mustafa Mir, Vikram Chaudhery, Brian Cunningham

The Optical Society of America and the SPIE local student chapters are sponsoring the 2nd iOptics seminar series.The series includes lectures from graduate students, post-docs and faculty working at …

http://nanohub.org/resources/8646

Illinois iOptics Lecture 3: A tissue scattering-phase theorem

17 May 2010 | Online Presentations | Contributor(s): Gabriel Popescu

We have derived two mathematical relationships between quantitative phase images of thin tissue slices and the scattering parameters of the bulk, i.e. scattering mean free path, ls, and anisotropy …

http://nanohub.org/resources/8960

Illinois iOptics Lecture 5: Deposited Nanorod Films for Biosensor Applications

17 May 2010 | Online Presentations | Contributor(s): Brian Cunningham

Planar photonic crystals have been used as the basis of many biological sensing devices. Here, we successfully demonstrated that the combination of a photonic crystal structure and a dielectric …

http://nanohub.org/resources/8962

Illinois iOptics Lecture 2: Curavature induced time-domain impedance

17 May 2010 | Online Presentations | Contributor(s): Jont B. Allen

Abstract for this talk is available as a PDF in supporting materials. Click here to view. iOptics, University of Illinois, Urbana-Champaign, Optical Society of America (OSA), NCN@Illinois, …

http://nanohub.org/resources/8959

Illinois iOptics Lecture 1: Super Accuracy and Super-Resolution of Molecular Motors and Ion Channels

16 Apr 2010 | Online Presentations | Contributor(s): Paul R Selvin

The standard diffraction limit of light is about 250 nm, meaning that you cannot "resolve" objects closer than this distance. Despite this, we have come up with a method to measure individual …

http://nanohub.org/resources/8853