Physics 111: Non-Linear Spectroscopy and Magneto-Optics Part 2 (MNO) Physics 111 Advanced Laboratory. Professor Dmitry Budker This is the second of two videos accompanying the Non-Linear Spectroscopy and Magneto-Optics Experiment, providing students with an introduction to the theory, apparatus, and procedures. The experiment consists of three sections: (1) students learn to operate a diode laser system and characterize its performance using a Fabry-Perot spectrum analyzer, (2) Doppler-broadened laser-induced fluorescence and Doppler-free saturated absorption spectra of the rubidium D2 line (780 nm) are recorded and analyzed, and (3) the near-resonant magneto-optical rotation is investigated. Nonlinear light-atom interaction leads to spectacular manifestations of the resonant Faraday Effect - polarization plane rotation in a magnetic field applied along the direction of light propagation radically different from the linear case. In particular, narrow (~30 Hz) effective line widths are observed in this experiment corresponding to a rotation enhancement by some seven orders of magnitude compared to the linear Faraday rotation. http://advancedlab.org
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Tags: Physics 111: Non-Linear Spectroscopy and Magneto-Optics Part 2 (MNO)
Uploaded by: berkeleyphy111 ( Send Message ) on 19-09-2012.
Duration: 34m 46s
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Lec 1 - Physics 111: Atomic Physics (ATM) Part 1. Balmer Series
Lec 2 - Physics 111: Atomic Physics (ATM) Part 2. Zeeman Effect
Lec 3 - Physics 111: Beta Ray Spectroscopy (BRA)
Lec 4 - Physics 111: Brownian Motion in Cells (BMC)
Lec 5 - Physics 111: Instrumentation Section Lab Equipment (BSC)
Lec 6 - Physics 111: Bubble Chamber (BBC)
Lec 7 - Physics 111: Carbon Dioxide Laser (CO2)
Lec 8 - Physics 111: Compton Scattering (COM)
Lec 9 - Physics 111: Gamma Ray Spectroscopy (GMA)
Lec 10 - Physics 111: Hall Effect In A Plasma (HAL)
Lec 11 - Physics 111: Holography (HOL)
Lec 12 - Physics 111: Introduction to Error Analysis
Lec 13 - Physics 111: Josephson Junction Effect (JOS)
Lec 14 - Physics 111: Radiation and Laboratory Safety
Lec 15 - Physics 111: Laser Safety
Lec 16 - Physics 111: Atomic Physics (ATM) Theory Lecture ONLY
Lec 17 - Physics 111: Energy Levels Lecture Part 1
Lec 18 - Physics 111: Energy Levels Lecture Part 2
Lec 19 - Physics 111 Light Sources and Detectors Lecture
Lec 20 - Physics 111: Optical Instruments Lecture
Lec 21 - Physics 111: Energy Transitions Lecture Series
Lec 22 - Physics 111: Laser Induced Fluorescence and Raman Scattering (LIF)
Lec 23 - Physics 111: Low Light Signal Measurements (LLS)
Lec 24 - Physics 111: Non-Linear Spectroscopy and Magneto-Optics Part 1 (MNO)
Lec 26 - Physics 111: Atom Trapping (MOT)
Lec 27 - Physics 111: Muon Lifetime (MUO)
Lec 28 - Physics 111: Non-Linear Dynamics and Chaos (NLD)
Lec 29 - Physics 111: Nuclear Magnetic Resonance (NMR) Part-1 Continuous Wave
Lec 30 - Physics 111: Nuclear Magnetic Resonance Part-2 Pulsed NMR
Lec 31 - Physics 111: Optical Pumping (OPT)
Lec 32 - Physics 111: How to do an Oral Report
Lec 33 - Physics 111: Optical Trapping (OTZ)
Lec 34 - Physics 111: Rutherford Scattering (RUT)
Lec 35 - Physics 111: Hall Effect In A Semiconductor