Difference between revisions of "MAB Papers"

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(MAB Design)
(MAB Design)
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* '''DeKieviet, M.; Durr, M.; Epp, S.; Lang, F.; Theis, M., Source for atomic beams of metastable gases: Design and performance. Review of Scientific Instruments 2004, 75 (2), 345-348.''' [http://cires.colorado.edu/jimenez-group/MAB/MAB_Research/Background_Papers/MAB_Design/DeKieviet-2004.pdf pdf]
 
* '''DeKieviet, M.; Durr, M.; Epp, S.; Lang, F.; Theis, M., Source for atomic beams of metastable gases: Design and performance. Review of Scientific Instruments 2004, 75 (2), 345-348.''' [http://cires.colorado.edu/jimenez-group/MAB/MAB_Research/Background_Papers/MAB_Design/DeKieviet-2004.pdf pdf]
- Microstructured electrode, our design 4
+
** Microstructured electrode, our design 4
- Flux ~10^14 metastable atoms/sr/sec
+
** Flux ~10^14 metastable atoms/sr/sec
  
  
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* '''Faubert, D.; Paul, G. J. C.; Giroux, J.; Bertrand, M. J., SELECTIVE FRAGMENTATION AND IONIZATION OF ORGANIC-COMPOUNDS USING AN ENERGY-TUNABLE RARE-GAS METASTABLE BEAM SOURCE. International Journal of Mass Spectrometry and Ion Processes 1993, 124 (1), 69-77.''' [http://cires.colorado.edu/jimenez-group/MAB/MAB_Research/Background_Papers/MAB_Design/Faubert-1993.pdf pdf]
 
* '''Faubert, D.; Paul, G. J. C.; Giroux, J.; Bertrand, M. J., SELECTIVE FRAGMENTATION AND IONIZATION OF ORGANIC-COMPOUNDS USING AN ENERGY-TUNABLE RARE-GAS METASTABLE BEAM SOURCE. International Journal of Mass Spectrometry and Ion Processes 1993, 124 (1), 69-77.''' [http://cires.colorado.edu/jimenez-group/MAB/MAB_Research/Background_Papers/MAB_Design/Faubert-1993.pdf pdf]
- Similar to our design 2 that we spoke to Beaugrand about.
+
** Similar to our design 2 that we spoke to Beaugrand about.
- In the paper they show that they use a skimmer, not an off-axis cathode?
+
** In the paper they show that they use a skimmer, not an off-axis cathode?
- Flux 1.5x10^15 metastable atoms/sr/sec
+
** Flux 1.5x10^15 metastable atoms/sr/sec
 +
 
  
 
* '''Harris, G. A.; Fernandez, F. M., Simulations and Experimental Investigation of Atmospheric Transport in an Ambient Metastable-Induced Chemical Ionization Source. Analytical Chemistry 2009, 81 (1), 322-329.''' [http://cires.colorado.edu/jimenez-group/MAB/MAB_Research/Background_Papers/MAB_Design/Harris-2009MetastableCI.pdf pdf]
 
* '''Harris, G. A.; Fernandez, F. M., Simulations and Experimental Investigation of Atmospheric Transport in an Ambient Metastable-Induced Chemical Ionization Source. Analytical Chemistry 2009, 81 (1), 322-329.''' [http://cires.colorado.edu/jimenez-group/MAB/MAB_Research/Background_Papers/MAB_Design/Harris-2009MetastableCI.pdf pdf]

Revision as of 09:18, 17 July 2009


MAB Design

  • Ashmore, J. P.; Sang, R. T., Cathode design for a low-velocity metastable neon cold cathode discharge source. Measurement Science & Technology 2001, 12 (4), N17-N21. pdf


  • Auday, G.; Guillot, P.; Galy, J.; Brunet, H., Experimental study of the effective secondary emission coefficient for rare gases and copper electrodes. Journal of Applied Physics 1998, 83 (11), 5917-5921. pdf


  • Baker, M.; Palmer, A. J.; Sang, R. T., A high flux metastable atomic discharge source with three-dimensional translation. Measurement Science & Technology 2003, 14 (4), N5-N8.


  • Berkout, V. D.; Doroshenko, V. M., Fragmentation of phosphorylated and singly charged peptide ions via interaction with metastable atoms. International Journal of Mass Spectrometry 2008, 278 (2-3), 150-157.


  • DeKieviet, M.; Durr, M.; Epp, S.; Lang, F.; Theis, M., Source for atomic beams of metastable gases: Design and performance. Review of Scientific Instruments 2004, 75 (2), 345-348. pdf
    • Microstructured electrode, our design 4
    • Flux ~10^14 metastable atoms/sr/sec


  • Dos Santos, F. P.; Perales, F.; Leonard, J.; Sinatra, A.; Wang, J.; Pavone, F. S.; Rasel, E.; Unnikrishnan, C. S.; Leduc, M., Efficient magneto-optical trapping of a metastable helium gas. European Physical Journal-Applied Physics 2001, 14 (1), 69-76. pdf


  • Dumas, M. E.; Debrauwer, L.; Beyet, L.; Lesage, D.; Andre, F.; Paris, A.; Tabet, J. C., Analyzing the physiological signature of anabolic steroids in cattle urine using pyrolysis/metastable atom bombardment mass spectrometry and pattern recognition. Analytical Chemistry 2002, 74 (20), 5393-5404.


  • Fahey, D. W.; Parks, W. F.; Schearer, L. D., HIGH-FLUX BEAM SOURCE OF THERMAL RARE-GAS METASTABLE ATOMS. Journal of Physics E-Scientific Instruments 1980, 13 (4), 381-383. pdf


  • Faubert, D.; Paul, G. J. C.; Giroux, J.; Bertrand, M. J., SELECTIVE FRAGMENTATION AND IONIZATION OF ORGANIC-COMPOUNDS USING AN ENERGY-TUNABLE RARE-GAS METASTABLE BEAM SOURCE. International Journal of Mass Spectrometry and Ion Processes 1993, 124 (1), 69-77. pdf
    • Similar to our design 2 that we spoke to Beaugrand about.
    • In the paper they show that they use a skimmer, not an off-axis cathode?
    • Flux 1.5x10^15 metastable atoms/sr/sec


  • Harris, G. A.; Fernandez, F. M., Simulations and Experimental Investigation of Atmospheric Transport in an Ambient Metastable-Induced Chemical Ionization Source. Analytical Chemistry 2009, 81 (1), 322-329. pdf


  • Kawanaka, J.; Hagiuda, M.; Shimizu, K.; Shimizu, F.; Takuma, H., GENERATION OF AN INTENSE LOW-VELOCITY METASTABLE-NEON ATOMIC-BEAM. Applied Physics B-Photophysics and Laser Chemistry 1993, 56 (1), 21-24. pdf


  • Leasure, E. L.; Mueller, C. R.; Ridley, T. Y., HOT, METASTABLE ATOM, MOLECULAR-BEAM SOURCE. Review of Scientific Instruments 1975, 46 (5), 635-637. pdf


  • Palmer, A. J.; Baker, M.; Sang, R. T., Quantitative comparison of rare-gas cold cathode discharge metastable atomic beam sources. Review of Scientific Instruments 2004, 75 (11), 5056-5058. pdf


  • Searcy, J. Q., SUPERSONIC MOLECULAR-BEAM METASTABLE ATOM SOURCE INITIATED BY DIRECT DISCHARGE. Review of Scientific Instruments 1974, 45 (4), 589-590. pdf


  • Weiser, C.; Siska, P. E., MAGNETIC DEFLECTION ANALYSIS OF SUPERSONIC METASTABLE ATOM BEAMS. Review of Scientific Instruments 1987, 58 (11), 2124-2130. pdf

Metastable Flux

  • Dunning, F. B.; Rundel, R. D.; Stebbings, R. F., DETERMINATION OF SECONDARY-ELECTRON EJECTION COEFFICIENTS FOR RARE-GAS METASTABLE ATOMS. Review of Scientific Instruments 1975, 46 (6), 697-701. pdf


  • Halfmann, T.; Koensgen, J.; Bergmann, K., A source for a high-intensity pulsed beam of metastable helium atoms. Measurement Science & Technology 2000, 11 (10), 1510-1514. pdf


  • Mason, N. J.; Newell, W. R., A STATE SELECTIVE METASTABLE DETECTOR. Measurement Science & Technology 1991, 2 (6), 568-570. pdf


  • Ohno, K.; Takami, T.; Mitsuke, K.; Ishida, T., STATE-RESOLVED COLLISION ENERGY-DEPENDENCE OF PENNING IONIZATION CROSS-SECTIONS FOR N2 AND CO2 BY HE-STAR-23S. Journal of Chemical Physics 1991, 94 (4), 2675-2687. pdf


  • Traitlor Thesis, 2002. pdf

Metastable Cross Sections

  • Abolmasov, S. N.; Samukawa, S., Cold-cathode Penning discharge-based ionizer for detection of hyperthermal neutral beams. Review of Scientific Instruments 2007, 78 (7). pdf


  • Alberti, M.; Lucas, J. M.; Brunetti, B.; Pirani, F.; Stramaccia, M.; Rosi, M.; Vecchiocattivi, F., Anisotropy effects in methyl chloride ionization by metastable neon atoms at thermal energies. Journal of Physical Chemistry A 2000, 104 (7), 1405-1415.pdf


  • Brunetti, B.; Candori, P.; Falcinelli, S.; Vecchiocattivi, F.; Sassara, A.; Chergui, M., Dynamics of the Penning ionization of fullerene molecules by metastable neon atoms. Journal of Physical Chemistry A 2000, 104 (25), 5942-5945.pdf


  • Carazzato, D.; Bertrand, M. J., CHARACTERIZATION OF A GLOW-DISCHARGE ION-SOURCE FOR THE MASS-SPECTROMETRIC ANALYSIS OF ORGANIC-COMPOUNDS. Journal of the American Society for Mass Spectrometry 1994, 5 (4), 305-315.pdf


  • Celotta, R.; Brown, H.; Molof, R.; Bederson, B., MEASUREMENTS OF TOTAL CROSS SECTION FOR SCATTERING OF LOW-ENERGY ELECTRONS BY METASTABLE ARGON. Physical Review A 1971, 3 (5), 1622-&.pdf


  • Koizumi, K.; Ohoyama, H.; Kasai, T., Collision-energy resolved steric effect on the Penning ionization reaction of tert-butyl bromide and Kr(P-3). Chemical Physics Letters 2003, 378 (5-6), 486-492.pdf


  • Okada, S.; Ohoyama, H.; Kasai, T., Probing branching mechanism through resonance-type oscillation in the collision-energy dependence of Penning ionization reaction of Ar (P-3) with oriented CH3I. Journal of Chemical Physics 2003, 119 (14), 7131-7138.pdf


  • Schappe, R. S.; Schulman, M. B.; Anderson, L. W.; Lin, C. C., MEASUREMENTS OF CROSS-SECTIONS FOR ELECTRON-IMPACT EXCITATION INTO THE METASTABLE LEVELS OF ARGON AND NUMBER DENSITIES OF METASTABLE ARGON ATOMS. Physical Review A 1994, 50 (1), 444-461.pdf


  • Yamato, M.; Ohoyama, H.; Kasai, T., 2D-measurement of Penning ionization cross section upon molecular orientation and collision energy in Ar(P-3(2,0))+CHCl3 crossed beam reaction. Journal of Physical Chemistry A 2001, 105 (13), 2967-2972.pdf


  • Yoshida, H.; Kawamura, H.; Ukai, M.; Kouchi, N.; Hatano, Y., DEEXCITATION CROSS-SECTIONS OF AR(3P2, 3P1, 3P0, AND 1P1) BY CH4, SIH4, AND GEH4. Journal of Chemical Physics 1992, 96 (6), 4372-4377.pdf


Metastable Background

  • Anderson, D. R.; Bierbaum, V. M.; Depuy, C. H.; Grabowski, J. J., FLOWING AFTERGLOW STUDIES OF ORGANIC POSITIVE-IONS GENERATED BY PENNING IONIZATION USING METASTABLE ARGON ATOMS. International Journal of Mass Spectrometry and Ion Processes 1983, 52 (1), 65-94. pdf


  • Miller, W. H., THEORY OF PENNING IONIZATION .1. ATOMS. Journal of Chemical Physics 1970, 52 (7), 3563-&. pdf
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