Laboratory for Optical Physics and Engineering CO + and C 2 Spectra Generated by CO 2 Atmospheric Pressure Glow Discharge in MicroChannels Chul Shin, Thomas.

Slides:

Advertisements

Similar presentations

Alex.A. Samarian and Brian.W. James School of Physics, University of Sydney, NSW 2006, Australia Sheath edge location The charge of dust particles in sheath.

Advertisements

© 2009 SRI International Laboratory measurement of the CO Cameron bands and visible emissions following EUV photodissociation of CO 2 Konstantinos S. Kalogerakis,

The Heavy Ion Fusion Virtual National Laboratory Experimental Evaluation of a Negative Ion Source for a Heavy Ion Fusion Driver L. R. Grisham (PPPL) S.K.

AA and Atomic Fluorescence Spectroscopy Chapter 9

23 June Performance of a Continuous Supersonic Expansion Discharge Source Evaluated by Laser-Induced Fluorescence Spectroscopy.

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

MODELING OF H 2 PRODUCTION IN Ar/NH 3 MICRODISCHARGES Ramesh A. Arakoni a), Ananth N. Bhoj b), and Mark J. Kushner c) a) Dept. Aerospace Engr, University.

EE 403 (or 503) Introduction to plasma Processing Fall 2011 Title of the project Your name.

Project NTP Van Ortega Cayetano Shama Karu Sean McKeown Themistoklis Zacharatos Advisor: Dr. Woo Lee Plasma Specialist: Dr. Kurt Becker Powered by:

MULTISCALE SIMULATION OF FUNCTIONALIZATION OF SURFACES USING ATMOSPHERIC PRESSURE DISCHARGES * Ananth N. Bhoj a) and Mark J. Kushner b) a) Department of.

University of Illinois Optical and Discharge Physics SPEED AND SELECTIVITY: CUSTOM WAVEFORMS 200 V (Slow, selective) MASK SiO 2 Si  15 mTorr, Ar/C 4 F.

FTIR ANALYSIS OF THE FLOWING AFTERGLOW FROM A HIGH-FREQUENCY SPARK DISCHARGE ALLEN R. WHITE Department of Mechanical Engineering Rose-Hulman Institute.

Agilent 7500 ICP-MS Date: 28JUL2005.

VUV PHOTON SOURCE OF A MICROWAVE EXCITED MICROPLASMAS AT LOW PRESSURE*

Submillimeter spectroscopic diagnostics in a semiconductor processing plasma Yaser H. Helal, Christopher F. Neese, Jennifer A. Holt, Frank C. De Lucia.

Electron interactions with CO 2 Bob Merlino Department of Physics and Astronomy The University of Iowa Iowa City, IA U. S. Department of Energy National.

Development of special generators of low-temperature plasma for ecological and biomedical applications. Research and Educational Center on Basic Problems.

Michael A. Chaszeyka Non-Equilibrium Thermodynamics Laboratory Absolute OH Number Density Measurements in Lean Fuel-Air Mixtures Excited by a Repetitively.

TRIGGERING EXCIMER LASERS BY PHOTOIONIZATION FROM A CORONA DISCHARGE* Zhongmin Xiong and Mark J. Kushner University of Michigan Ann Arbor, MI USA.

Reforming and Fixation of Carbon Oxides in Atmospheric Pressure Non- thermal CO/CO 2 Plasmas Robert Geiger Advisor: Dr. David Staack Texas A&M Mechanical.

Laboratory for Optical Physics and Engineering MOLECULAR SPECTROSCOPY OF RARE EARTH AND METAL-HALIDE MOLECULES International Symposium on Molecular Spectroscopy.

Laboratory of Molecular Spectroscopy & Nano Materials, Pusan National University, Republic of Korea Spectroscopic Identification of New Aromatic Molecular.

Yiting Zhangb, Mark Denninga, Randall S. Urdahla and Mark J. Kushnerb

HiCAT- a Novel Diagnostic for Mass Loss and Species Composition Analysis Goal: Provide In-situ, real time characterization of ablated/ vaporized materials.

Nonequilibrium Thermodynamics Laboratories The Ohio State University Chemi-Ionization and Visible/UV Emission from Supersonic Flows of Combustion Products.

Plasma diagnostics using spectroscopic techniques

Spectral plasma diagnostics by molecular spectra and continuum Petr Vašina and Jan Janča Department of Physical Electronics, Masaryk University, Brno,

VUV-diagnostics of inelastic collision processes in low temperature hydrogen plasmas J. Komppula & JYFL ion source group University of Jyväskylä Department.

Preliminary work on microplasmas and APGDs Paul Bryant Department of Electrical Engineering and Electronics, Brownlow Hill, University.

11/8/ Microplasma Optical Emission Spectrometer (MOES) on a chip SFR Workshop November 8, 2000 Michiel Krüger, David Hsu, Scott Eitapence, K. Poolla,

Laboratory of Molecular Spectroscopy, Pusan National University, Pusan, Republic of Korea Spectroscopic identification of isomeric trimethylbenzyl radicals.

Gregory ClarkeTechnological Plasmas Research Group Time resolved diagnostics for pulsed magnetron plasmas.

Liquid Oxygen is Blue, Why? The electronic properties of oxygen (i.e. the distribution of electrons) give rise to some interesting optical properties -

Waves in a 2D Dusty Plasma Crystal

Response of the Earth’s environment to solar radiative forcing

DIODE-LASER AND FOURIER-TRANSFORM SPECTROSCOPY OF 14 NH 3 AND 15 NH 3 IN THE NEAR-INFRARED (1.5 µm) Nofal IBRAHIM, Pascale CHELIN, Johannes ORPHAL Laboratoire.

1 The Red Rectangle Nebula excited by excited species Nadine Wehres, Claire Romanzin, Hans Van Winckel, Harold Linnartz, Xander Tielens.

1 Pengqian Wang Department of Physics Western Illinois University March 4, 2013.

Decomposition rate of benzene increases almost linearly against time, and it tends to be constant around 200s. While the decomposition rate increases,

IMPACT Laboratory investigations of electrostatic dust lofting on comet and asteroid (airless bodies) surfaces Xu Wang Joseph Schwan, Hsiang-Wen Hsu, Mihály.

Main Title Manori Perera 1 and Ricardo Metz University of Massachusetts Amherst 64 th International Symposium on Molecular Spectroscopy June 25th, 2009.

An Estimation of Critical Electron Density at Just Starting Breakdown in Gases Mase. H Professor Emeritus of Ibaraki University.

Spatial distributions in a cold strontium Rydberg gas Graham Lochead.

High-resolution Fourier transform emission spectroscopy of the A 2  + – X 2  transition of the BrCN + ion. June 20, 2005, Ohio state Univ. Yoshihiro.

Many mass spectra are observed in addition to those of nitrogen (28amu) and benzene (78amu) molecules between 1 and 80amu, when the discharge is not generated.

56 th Annual Meeting of the Division of Plasma Physics. October 27-31, New Orleans, LA Using the single reservoir model [3], shown on right, to:

Initial Development of High Precision, High Resolution Ion Beam Spectrometer in the Near- Infrared Michael Porambo, Brian Siller, Andrew Mills, Manori.

High Precision Mid-IR Spectroscopy of 12 C 16 O 2 : ← Band Near 4.3 µm Jow-Tsong Shy Department of Physics, National Tsing Hua University,

BORONYL MIMICS GOLD: A PHOTOELECTRON SPECTROSCOPY STUDY Tian Jian, Gary V. Lopez, Lai-Sheng Wang Department of Chemistry, Brown University International.

Time-Resolved IR and Mass Spectroscopy of Laser-Ablated Magnesium

Detection of Perfluorinated Compounds By High-Pressure Microplasma Optical Emission Spectroscopy SFR Workshop November 8, 2000 David Hsu, Michiel Krüger,

CORRECTIONS TO AB INITIO CESIUM-ARGON INTERACTION POTENTIALS DETERMINED BY SIMULATION OF FREE→FREE ABSORPTION SPECTRA Darby Hewitt, Thomas Spinka, Jason.

Dissociation of Molecular Ions Studied by

Observation of Quantum Beating in Rubidium at 2. 1 THz and 18

Spin Polarization Spectroscopy of

PLASMA DYNAMICS AT THE IONIZATION FRONT OF HIGH

Seok-geun Lee, Young-hwa An, Y.S. Hwang

Scott E. Dubowsky, Amber N. Rose, Nick Glumac, Benjamin J. McCall

Wendy W. Chen, Thomas C. Galvin, Thomas J. Houlahan, and J. Gary Eden

Using Molecular Dissociation to Determine the Efficiency of a

DOE Plasma Science Center Control of Plasma Kinetics

Participation IAP NAS of Ukraine in understanding of vacuum breakdown phenomena Iaroslava Profatilova, V.Baturin, O. Karpenko.

SIMULATIONS OF HIGH-PRESSURE CATHODIC

N2 Vibrational Temperature, Gas Temperature,

PLASMA DIAGNOSTICS IN AIR PLASMAS CONTAINING WATER DROPLETS

DECOMPOSITION PROCESS OF BENZENE IN A LOW PRESSURE GLOW DISCHARGE

COOLING OF ELECTRICALLY-EXCITED He2 IN A MICROCAVITY PLASMA JET

CONTROLLING REACTIVE OXYGEN AND NITROGEN SPECIES (RONS) PRODUCTION BY ATMOSPHERIC PRESSURE PLASMA JETS USING GAS SHIELDS* Seth A. Norberga), Ansgar Schmidt-Blekerb),

IDENTIFYING THE DOMINANT IONS IN ARGON PLASMAS: DEI, DAI, AND Ar2+

Observation of Broadband Ultraviolet Emissions From Hg3*

Presentation transcript:

Laboratory for Optical Physics and Engineering CO + and C 2 Spectra Generated by CO 2 Atmospheric Pressure Glow Discharge in MicroChannels Chul Shin, Thomas J. Houlahan, Zhen Dai, Sung-Jin Park and J. Gary Eden University of Illinois 1406 W. Green St., Urbana, IL, June 16, 2014

Laboratory for Optical Physics and Engineering MOTIVATION Microcavity plasmas provide a unique platform for molecular spectroscopy: –Electron temperature of 1-10 eV –Specific power loadings up to 1 MW/cm 3 –Electron densities of cm -3 –Operating pressures up to and beyond 1 atm Demonstrate microplasma capacity with CO –Ionization potential of CO: ~14 eV Microplasmas are an efficient source of highly-excited diatomic neutrals and ions

Laboratory for Optical Physics and Engineering SYSTEM ARRANGEMENT CO 2 Ar H2H2 MFC Manometer Device Port Check Valve Vent Spectrophotometer (ICCD) Premixing Chamber Lens Optical Rail

Laboratory for Optical Physics and Engineering DEVICE DIMENSIONS 500 μm 100 μm 160 μm 40 μm Al 2 O 3 Al

Laboratory for Optical Physics and Engineering OPERATION AT ONE ATMOSPHERE - f = 20 kHz sine wave - V opeation ~2 kV rms 5 mm

Laboratory for Optical Physics and Engineering PANORAMIC: nm

Laboratory for Optical Physics and Engineering COMET TAIL BAND SYSTEM 5 W, 60 SCCM CO 2

Laboratory for Optical Physics and Engineering SWAN SYSTEM 5 W, 60 SCCM CO 2

Laboratory for Optical Physics and Engineering POWER DEPENDENCE 60 SCCM CO 2

Laboratory for Optical Physics and Engineering POWER DEPENDENCE 60 SCCM CO 2

Laboratory for Optical Physics and Engineering SUMMARY Optical emission from dissociating pure CO 2 has been demonstrated CO + Comet Tail Band System dominates ultraviolet/visible emission Microplasmas are an efficient source of highly- excited diatomic neutrals and ions

Laboratory for Optical Physics and Engineering Thank You!

Laboratory for Optical Physics and Engineering REFERENCES [1] Pearse, R. W. B., Gaydon, A. G., Pearse, R. W. B., & Gaydon, A. G. (1976). The identification of molecular spectra (Vol. 297, p. 293). London: Chapman and Hall.

Laboratory for Optical Physics and Engineering OPTICAL EMISSION SPECTRUM OF CO 2 MICROPLASMA