Resonant Faraday Rotation in a Hot Lithium Vapor Scott Waitukaitis University of Arizona, Department of Physics May 2007.

Slides:

Advertisements

Similar presentations

Light Waves and Polarization Xavier Fernando Ryerson Communications Lab

Advertisements

Optical sources Lecture 5.

Measuring the Speed of Light via an Open Cavity HeNe Laser James D. White, Daniel J. D’Orazio, Mark J. Pearson, Justin T. Schultz, Daniel Sidor, Michael.

HeNe Laser Mode Sweep The following animation illustrates how the longitudinal modes of a typical mW HeNe laser sweep or cycle through the neon gain.

Using an Atomic Non-Linear Generated Laser Locking Signal to Stabalize Laser Frequency Gabriel Basso (UFPB), Marcos Oria (UFPB), Martine Chevrollier (UFPB),Thierry.

Types of Waves Harmonic Waves Sound and Light Waves

May Chuck DiMarzio, Northeastern University ECE-1466 Modern Optics Course Notes Part 9 Prof. Charles A. DiMarzio Northeastern University.

Single Mode Stabilization of Diode Lasers Ryan Courreges.

PRECISION CAVITY ENHANCED VELOCITY MODULATION SPECTROSCOPY Andrew A. Mills, Brian M. Siller, Benjamin J. McCall University of Illinois, Department of Chemistry.

PHY132 Introduction to Physics II Class 3 – Outline: Ch. 21, sections The Principle of Superposition Standing Waves Nodes and Antinodes Musical.

HP/Agilent 5517 Zeeman-Split HeNe Laser Mode Sweep Sam’s Laser FAQ ( Copyright © , Samuel M. Goldwasser,

Study of the Faraday Effect In the Laboratory Conducted by Andreas Gennis and Jason Robin Presented by Andreas Gennis The Basis of the Faraday Effect The.

Sam’s Laser FAQ ( Copyright © , Samuel M. Goldwasser, All Rights Reserved. HeNe Laser Mode Sweep The.

Ruby Laser Crystal structure of sapphire: -Al2O3 (aluminum oxide). The shaded atoms make up a unit cell of the structure. The aluminum atom inside the.

5. Lasers. Introduction to Lasers Laser Acupuncture, Laser Scalpel and Laser W/R Head.

COMPUTER MODELING OF LASER SYSTEMS

Atomic spectra are a result of energy level diagrams - quantum theory.

EM Radiation Sources 1. Fundamentals of EM Radiation 2. Light Sources 3. Lasers.

Dr. Jie ZouPHY Chapter 18 Superposition and Standing Waves (Cont.)

Lab 11: Waves and Sound University of Michigan Physics Department Mechanics and Sound Intro Labs.

Hyperfine Studies of Lithium using Saturated Absorption Spectroscopy Tory Carr Advisor: Dr. Alex Cronin.

Cavity QED as a Deterministic Photon Source Gary Howell Feb. 9, 2007.

Fiber-Optic Communications James N. Downing. Chapter 2 Principles of Optics.

Diode laser The diode or semiconductor laser Diode lasers are extremely compact (0.3×0.2×0.1 mm), high efficiency (up to 40%), tuneable lasers, which have.

References Acknowledgements This work is funded by EPSRC 1.R. P. Abel, U. Krohn, P. Siddons, I. G. Hughes & C. S. Adams, Opt Lett (2009). 2.A.

Stimulated Raman scattering If high enough powered radiation is incident on the molecule, stimulated Anti-Stokes radiation can be generated. The occurrence.

Construction of a Laser Frequency Stabilization System for a Magneto Optical Trap Talia Martin and Dr. Edward Deveney Department of Physics, Bridgewater.

K L University 1 By G.SUNITA DEPARTMENT OF PHYSICS.

Designing High Power Single Frequency Fiber Lasers Dmitriy Churin Course OPTI

Angus Henderson, Paul Hoffman and Ryan Stafford

Ultrafast Experiments Hangwen Guo Solid State II Department of Physics & Astronomy, The University of Tennessee.

Optics, Eugene Hecht, Chpt. 13;

. Random Lasers Gregor Hackenbroich, Carlos Viviescas, F. H.

§ 4 Optical Fiber Sensors

Measurements with the KSTAR Beam Emission Spectroscopy diagnostic system Máté Lampert Wigner Research Centre for Physics Hungarian Academy of Sciences.

October 16-18, 2012Working Group on Space-based Lidar Winds 1 AEOLUS STATUS Part 1: Design Overview.

IR/THz Double Resonance Spectroscopy in the Pressure Broadened Regime: A Path Towards Atmospheric Gas Sensing Sree H. Srikantaiah Dane J. Phillips Frank.

Controlling the dynamics time scale of a diode laser using filtered optical feedback. A.P.A. FISCHER, Laboratoire de Physique des Lasers, Universite Paris.

ECE 455: Optical Electronics Lecture #9: Inhomogeneous Broadening, the Laser Equation, and Threshold Gain Substitute Lecturer: Tom Spinka Tuesday, Sept.

Solution Due to the Doppler effect arising from the random motions of the gas atoms, the laser radiation from gas-lasers is broadened around a central.

1 Optic Rotation Project I Doppler-free saturated absorption spectrum Lei Huang Department of Physics and Astronomy SUNY at Stony Brook May. 4 th, 2005.

High Precision Mid-Infrared Spectroscopy of 12 C 16 O 2 : Progress Report Speaker: Wei-Jo Ting Department of Physics National Tsing Hua University

N. Yugami, Utsunomiya University, Japan Generation of Short Electromagnetic Wave via Laser Plasma Interaction Experiments US-Japan Workshop on Heavy Ion.

Components of the Rubidium Apparatus Magnet: Confines the electron beam to go through the aperture separating the source and target chambers. Probe Laser:

Simple Multiwavelength Time-Division Multiplexed Light Source for Sensing Applications Thilo Kraetschmer and Scott Sanders Engine Research Center Department.

Lecture 6. Polarization splitter based Filters Acoustooptic Tunable Filters.

HIGH PRECISION MID-IR SPECTROSCOPY OF N2O NEAR 4.5 μm Wei-jo (Vivian) Ting and Jow-Tsong Shy Department of Physics National Tsing Hua University Hsinchu,

Haifeng Huang and Kevin K. Lehmann

LIGO-G09xxxxx-v1 Form F v1 Development of a Low Noise External Cavity Diode Laser in the Littrow Configuration Chloe Ling LIGO SURF 2013 Mentors:

I.Introduction II. System Design B.E. Unks, N. A. Proite, D. D. Yavuz University of Wisconsin – Madison The above figure shows a block diagram of the apparatus.

Non-ideal Cavity Ring-Down Spectroscopy: Linear Birefringence, Linear Polarization Dependent Loss of Supermirrors, and Finite Extinction Ratio of Light.

Department of Mechanical Engineering Students: Seth Davies, Betsy Farris, Alex Mende, Constantino Tadiello, Joseph Williams Advisors: Jordan.

Chapter 11. Laser Oscillation : Power and Frequency

Tze-Wei Liu Y-C Hsu & Wang-Yau Cheng

A. Nishiyama a, K. Nakashima b, A. Matsuba b, and M. Misono b a The University of Electro-Communications b Fukuoka University High Resolution Spectroscopy.

Photo detector Circuitry and Hardware Relating to PARCS Rachelle Baker Mentor: Alex Cronin Department of Physics University of Arizona.

Frequency-comb referenced spectroscopy of v 4 =1 and v 5 =1 hot bands in the 1. 5 µm spectrum of C 2 H 2 Trevor Sears Greg Hall Talk WF08, ISMS 2015 Matt.

0 Frequency Gain 1/R 1 R 2 R 3 0 Frequency Intensity Longitudinal modes of the cavity c/L G 0 ( ) Case of homogeneous broadening R2R2 R3R3 R1R1 G 0 ( )

Date of download: 9/17/2016 Copyright © 2016 SPIE. All rights reserved. A schematic of a tunable external cavity diode laser in a Littman-Metcalf configuration.

ISMS 2017 at CHAMPAIGN-URBANA, ILLINOIS

Beryllium ions in segmented Paul trap

Light-Matter Interaction

Integrated Semiconductor Modelocked Lasers

Optical Feedback in a Curved-Facet Self-Pulsing Semiconductor Laser

A New Design for a Tunable External Cavity Diode Laser

Mapping vibrational modes of Si3N4 membrane - Ultrasonic Force Microscopies vs Laser Doppler Vibrometry The development of new micro and nano-electromechanical.

Principle of Mode Locking

Tunable Slow Light in Cesium Vapor

Laser oscillation Laser is oscillator

Jaynes-Cummings Hamiltonian

Presentation transcript:

Resonant Faraday Rotation in a Hot Lithium Vapor Scott Waitukaitis University of Arizona, Department of Physics May 2007

Overview Highly frequency dependent Can be enhanced near resonances

How does this work? Linearly polarized light is a superposition of equal parts RCP and LCP RCP and LCP have different indices Resulting rotation proportional to difference in indices, i.e.

The role of B: the Zeeman effect RCP light causes LCP light causes Via Zeeman effect, degeneracy in is lifted so that

Frequency dependence

Fine structure of lithium -3/2 -1/2 1/23/2-3/2 -1/2 1/2 -1/23/ nm nm nm nm Wavelength range ~0.04 nm Frequency range ~30 GHz

Added complexities Natural linewidth ~6 MHz Observed width ~3000 MHz Broadening mechanisms –Doppler broadening –Power broadening –Pressure broadening

What do we need to observe Faraday rotation? A laser that can be tuned over a 0.04 nm range around 670 nm A lithium vapor A way to infer rotation has occured

Diode laser basics ~0.5 cm  ~ 670 nm Wavelength is modulated via current adjustment –As wavelength changes so does output power

Laser output Mode profile governed by boundary conditions of lasing medium At a given temperature, lasing occurs where product of profiles is highest Both mode and gain profile change with temperature Dominant wavelength bounces from one mode to the next

Typical laser trace

Piezo driven external cavity Piezos driven by function generator and control circuit Able to adjust plate offset Able to adjust amplitude of plate oscillations

Heat pipe oven ~ 3 cm in diameter ~ 30 cm in length ~ K

Experimental setup

Data vs. model Most general features of data mimicked by model –Sign –Order of magnitude Model predicts more active features

Possible causes of discrepancy Hyperfine splitting in the ground state (~800 MHz) Saturation effects due to high intensity of laser beam Off-axis B field Large laser line width

Acknowledgments I’d like to thank Dr. Cronin for giving me the opportunity to work with him. I’d also like to thank Dr. Bickel for his advice along the way. My gratitude also goes out to Tori Carr, Yancey Sechrest, Vincent Lonij, Ben McMorran, John Perrault for their help and support as well.