Abstract: Nd: YAG laser (Quantel) 1.6J, 8nSec with a repetition rate of 30 Hz is used in the experiment of laser produced plasma. The substrate used in.

Slides:

Advertisements

Similar presentations

Thermal properties of laser crystal Rui Zhang ACCL Division V, RF-Gun Group Feb 20, 2015 SuperKEKB Injector Laser RF Gun Review.

Advertisements

Nonequilibrium Thermodynamics Laboratories The Ohio State University OH Laser-Induced Fluorescence Measurements in Nanosecond Pulse Discharge Plasmas Inchul.

Study of Radiative and Heat-Generating Recombination in GaAs Ryan Crum and Tim Gfroerer, Davidson College, Davidson, NC Mark Wanlass, National Renewable.

Bouncing Liquid Jets James Bomber, Dr. Thomas Lockhart Department of Physics and Astronomy, University of Wisconsin - Eau Claire

DYE LASERS Mehmet Mustafa KARABULUT. TABLE OF CONTENTS 1. Working Principles 2. CW and Pulse Modes 3. Applications 4. Properties 5. Recent.

MEG Experiments Stimulation and Recording Setup Educational Seminar Institute for Biomagnetism and Biosignalanalysis February 8th, 2005.

CCFE is the fusion research arm of the United Kingdom Atomic Energy Authority Real time operation of MAST TS diagnostic S. Shibaev, G. Naylor, R. Scannell,

Berkeley Nucleonics Corporation The Use of Digital Delay Generators in Laser Induced Breakdown Spectroscopy Applications.

Metal Repairs: Laser Welding. LASER  “light amplification by stimulated emission of radiation.”  Electrons are atomic particles that exist at specific.

Trilateral Euregio Cluster TEC Institut für Plasmaphysik Assoziation EURATOM-Forschungszentrum Jülich Development of in situ diagnostic for fuel retention,

LASER TEST OF Mo AND Cu MIRRORS

1 Laser Beam Coherence Purpose: To determine the frequency separation between the axial modes of a He-Ne Laser All sources of light, including lasers,

EMISSION SPECTROSCOPIC STUDIES OF LASER-INDUCED GRAPHITE PLASMAS László Nemes Research Laboratory for Materials and Environmental Chemistry, Chemical Research.

PRINCIPLES OF MEASUREMENT AND INSTRUMENTATION EKT 112

Diamond Radiator Development Brendan Pratt University of Connecticut GlueX Collaboration Meeting, Jefferson Lab, October 2011.

Core-Shell Nanoparticle Generation Using Laser Ablation Vanessa Coronado, Westside High School, Houston ISD Dr. Sy-Bor Wen/ Assistant Professor and YoungKyong.

M. S. Tillack, Y. Tao, F. Najmabadi Proposed contributions to Jupiter-III by the laser-matter interactions group Briefing to Prof. Yoshio Ueda 20 November.

K.Umstadter –-Laser+D on W PISCES Effects of transient heating events on W PFCs in a steady-state divertor-plasma environment Karl R. Umstadter, R. Doerner,

1 of 16 M. S. Tillack, Y. Tao, J. Pulsifer, F. Najmabadi, L. C. Carlson, K. L. Sequoia, R. A. Burdt, M. Aralis Laser-matter interactions and IFE research.

The Anatomy of a Digital Camera A digital camera contains hundreds of parts It is important to understand the most essential parts of the camera as you.

DIGITAL PHOTOGRAPHY: BACK TO BASICS Source:

Status of IPBSM Improvement N. Terunuma, KEK 2012/July/13 ATF2 Weekly Meeting.

Parts and Functions of a DSLR Camera

Chapter 5 Lecture 10 Spring Nonlinear Elements 1. A nonlinear resistance 2. A nonlinear reactance 3. A time varying element in you circuit or system.

30. Nov I.Will, G. Klemz, Max Born Institute: Optical sampling system Optical sampling system for detailed measurement of the longitudinal pulse.

Bouncing Liquid Jets James Bomber, Nick Brewer, and Dr. Thomas Lockhart Department of Physics and Astronomy, University of Wisconsin - Eau Claire

LASER BEAM MACHINING BY S.PREMKUMAR.

TIRF Total Internal Reflection Fluorescence Microscopy specialized fluorescence microscopy technique specifically images a very thin optical section (50-250nm)

October 30th, 2007High Average Power Laser Program Workshop 1 Long lifetime optical coatings for 248 nm: development and testing Presented by: Tom Lehecka.

Understand the Features of Security System LEACTURE -13.

Horizontal Deflection

FEMTOSECOND LASER FABRICATION OF MICRO/NANO-STRUCTURES FOR CHEMICAL SENSING AND DETECTION Student: Yukun Han MAE Department Faculty Advisors: Dr. Hai-Lung.

M. Zamfirescu, M. Ulmeanu, F. Jipa, O. Cretu, A. Moldovan, G. Epurescu, M. Dinescu, R. Dabu National Institute for Laser Plasma and Radiation Physics,

Ablative acceleration of thin metal plates on picosecond and nanosecond time scales (comparative study by acceleration efficiency and surface profilometry)

Shutter Inspection and Testing for new Teflon coated blades.

Observation of Bioluminescence in ANTARES J. Brunner.

Recent Results from Dragonfire Armor Simulation Experiments Farrokh Najmabadi, Lane Carlson, John Pulsifer UC San Diego HAPL Meeting, Naval Research Laboratory.

What is the Research Question?

1 An investigation into the breakdown mechanisms of a triggered water gap switch Mohsen Saniei Institute for Energy and Environment University of Strathclyde.

Characterization of Laser Energy Deposition for Active Flow Control Clark Pederson University of Arizona Advisor: Dr. Jesse Little, Assistant Professor,

Speed Sensor Calibration

On-line Sorting Technologies for CCA Treated Wood Sarasota Team Meeting June 5, 2001.

Workshop for advanced THz and Compton X-ray generation

The Digital Camera Canon Power Shot ELPH 100 HS.

Shutter Button ON/OFF Button Mode switch Flash Lens.

1 Progress of the Thomson Scattering Experiment on HSX K. Zhai, F.S.B. Anderson, D.T. Anderson HSX Plasma Laboratory, UW-Madison Bill Mason PSL, UW-Madison,

Non-reflective coating Good quality lenses in a camera reflect very little light and appear dark or slightly purple. A thin coating of a fluoride salt.

Spring Hill Assembly1 InnoSys Park Brake Tool Master Control Panel Screens 1 3-Mar-2008.

First Thomson Scattering Results on HSX K. Zhai, F.S.B. Anderson, and D.T. Anderson HSX Plasma Laboratory, U. of Wisconsin, Madison 1. Abstract 5. Summary.

3M Drug Delivery Systems 3 Chris Blatchford & Gemma Nixon, 3M Drug Delivery Systems, Morley St, Loughborough, UK. Graham Hargrave, Tim Justham & Edward.

D. Scarpa 1, P. Nicolosi 2,3, A. Franci 2, A. Tomaselli 6, M. Manzolaro 1, S. Corradetti 1,4, J. Vasquez 1,5, M. Rossignoli 1, M. Calderolla 1, A. Monetti.

Date of download: 6/18/2016 Copyright © 2016 SPIE. All rights reserved. The relative fluorescent lifetime algorithm introduces both hardware and software.

Yongjin Shin Sohee Park, Youngseop Kim, Jangwoen Lee, Woonggyu Jung, Zhongping Chen, and J. Stuart Nelson 1.

Roller Coaster Speed Sensor Calibration. Lab Safety  Do not stand on chairs, or sit or stand on the tables  Know the location of the first-aid kit 

Pulsed Laser Deposition and Quantum Efficency of Mg films University of Lecce L. Cultrera.

Yb:YAG Regenerative Amplifier for A1 Ground Laser Hut Rui Zhang ACCL Division V, RF-Gun Group Nov 20, 2015 SuperKEKB Injector Laser RF Gun Review.

Discharge-assisted LIBS and ablation-induced current pulses.

Date of download: 10/13/2017 Copyright © ASME. All rights reserved.

l 66TH MEETING OF THE ESRF l May 2014 l Author

Laser Beam Welding LIGHT AMPLIFICATION by STIMULATED EMISSION of RADIATION. Coalescence of heat is produced by the Laser beam which is having high energy.

DIGITAL PHOTOGRAPHY.

From: Deburring Effect of Plasma Produced by Nanosecond Laser Ablation

Impurity Transport Research at the HSX Stellarator

Date of download: 1/1/2018 Copyright © ASME. All rights reserved.

Date of download: 1/3/2018 Copyright © ASME. All rights reserved.

From: Magnetic Field Effects on Laser Drilling

From: Deburring Effect of Plasma Produced by Nanosecond Laser Ablation

Digital SLR and viewfinder

Metal Repairs: Laser Welding

Electron mode A B C D > 4 GeV e- θ g e- DR α PS

Presentation transcript:

Abstract: Nd: YAG laser (Quantel) 1.6J, 8nSec with a repetition rate of 30 Hz is used in the experiment of laser produced plasma. The substrate used in the experiment is a thin film of LiF (0.05  m)-C (0.5  m) coated on Pyrex substrate. As the flash lamp of the Nd: YAG is continuously ON, it has the capacity to ablate the film from the surface of the substrate. To prevent ablation a mechanical shutter assembly is introduced on the path of the laser. This shutter performed as interlock also and it was synchronized with the firing of the laser. The laser is fired on a single shot basis. The Circuit built for the shutter assembly was also used for triggering an ICCD camera so as to take the complete image of the laser produced Plasma Plume. The ICCD camera has inbuilt delay of the 200 nsec, so as to have t = 0, camera has to have a pretrigger of 200 nsec. The circuit controls Laser firing, Shutter opening, ICCD camera and Data Acquisition assembly. Control and Timing Sequence for Laser Produced plasma Institute for Plasma Research, Bhat, Gandhinagar Kiran Patel, S.Sunil, Chhaya, Ajai Kumar Introduction: Laser produce plasma involves ablation of thin film of LiF-C. LiF-C is coated on glass substrate and the film has a thickness of 0.55  m. Ablation procedure involves tight focusing of laser on the target plate using a lens to give spot size of 2 to 3mm and firing of Nd: YAG laser on single shot basis. Once the laser is fired the coating of the film is evaporated and for the next setup of the experiment a fresh coating is needed. This is done manually by a translator mechanism in which target plate is pushed in or pulled out along the axis of the laser. In this paper, an overview of the laser produce Plasma system will be presented, which will focus on the control and timing sequence for laser produce plasma. Basically, Control card design for three different operation First Control Nd:Yag laser to operate in Single shot Mode, Second Open the shutter only for short Duration to pass the laser, and third trigger ICCD camera to capture the image of the Plasma Plum. Description: ND:YAG Laser operated both in Continuous Mode and Single shot Mode. In Continuous Mode, Flash lamp and Q Switch operate continuous at repetition rate of 30 Hz. In Single Shot mode, Flash lamp continuous at 30 Hz but only Q Switch operates in single shot. First, To operate the laser in this mode a trigger pulse required for trigger the Q – Switch and this trigger pulse is come after 300 to 410  sec of Flash lamp Output pulse and flash lamp Output comes at repetition rate of 30 Hz. Second, In Single Shot Mode a Flash lamp continuous ablation of LiF-C coating of plate placed in experimental vessel. When laser is fired, some portion of the LiF-C coating is ablation by flash lamp. To prevent the flash lamp continuous ablation of LiF-C coating a Shutter is placed and shutter is open only shot duration when the laser pulse comes and other time shutter restrict the flash lamp. Control Sequence: To operate Laser in single shot mode, a Trigger Pulse A of 10  sec should be generated with a delay of nearly 300 to 410  sec from Flash Lamp output shown in Fig.2. Delay between Flash Lamp output and Trigger Pulse A is used for to change the Energy of the laser. By varying this delay laser energy change from 1.5 mJ to 3.6 mJ. Shutter required 50-msec duration for 45  of opening and remains open for the next 33 msec in witch at least one pulse comes. Hence, total 83.3 msec pulse required for Shutter.In Fig:3 Main trigger Pulse given from any Pulse Generator and from this trigger pulse a 83 msec pulse generated from monoshot to give a mechanical Shutter. Second a separate Pulse B of 33.3 msec generated from main trigger Pulse with a delay of 50 msec and finally Pulse A and Pulse B are ANDed and generate a Laser fire Pulse. Timing Diagram for Laser Operate in Single Shot External Mode Main Trigger 50 mSec Delay Pulse B 33.3 mSec 83.3 mSec Shutter Pulse Laser Produce Plasma Hardware Overview. SHUTTER LASER EXPERIMENTAL SETUP CONTROL CARD ICCD Timing Diagram for Laser Operation in Single Shot External Mode Delay Pulse 300 – 410 uSec Pulse A 10 uSec 33.3 mSec Flash Lamp Output 45 uSec 10 uSec 710 nSec Timing Sequence for ICCD Trigger 910 nSec Photo Diode Output 10 uSec Laser Fire Pulse PLASMA 2005