STUDIES OF DESORPTION AND SURFACE DIFFUSION BY PULSED LASER TECHNIQUES.

D. Burgess, I. Hussla, Peter C Stair, R. Viswanathan, E. Weitz

Research output: Chapter in Book/Report/Conference proceedingConference contribution

Abstract

Temperature programmed desorption (TPD) has been used extensively to investigate molecule-surface interactions. Recently, pulsed-laser-induced thermal desorption has been used to develop techniques for investigating molecular desorption dynamics and molecular surface diffusion. An understanding of pulsed-laser-induced thermal desorption is best obtained with reference to ordinary thermal desorption spectroscopy. In the reported study, the surface diffusion of CO on copper was studied by observing the time dependence for the recovery of the desorption flux from a small area on the Cu(100) surface following the depletion of the adsorbed CO in that area by a series of laser pulses. Measured diffusion coefficients range from 2 multiplied by 10** minus **7 cm**2sec** minus **1 at 110 K to 3. 5 multiplied by 10** minus **6 cm**2sec** minus **1 at 140 K. The approximate activation energy for diffusion derived from these measurements is 12 kJ/mole. An investigation of the desorption and decomposition of formaldehyde on clean and oxidized copper surfaces using pulsed-laser-induced thermal desorption is currently in progress. These experiments are designed to determine whether the thermal chemistry observed with ordinary thermal desorption can be altered using the very fast heating and cooling possible with the pulsed laser technique. Results of these experiments are discussed.

Original languageEnglish
Title of host publicationAmerican Chemical Society, Division of Petroleum Chemistry, Preprints
PublisherACS
Pages721
Number of pages1
Volume29
Edition3
Publication statusPublished - Aug 1984

Fingerprint

Thermal desorption
Surface diffusion
Pulsed lasers
Desorption
Thermal desorption spectroscopy
Copper
Temperature programmed desorption
Formaldehyde
Laser pulses
Activation energy
Experiments
Fluxes
Cooling
Decomposition
Heating
Recovery
Molecules

ASJC Scopus subject areas

  • Fuel Technology

Cite this

Burgess, D., Hussla, I., Stair, P. C., Viswanathan, R., & Weitz, E. (1984). STUDIES OF DESORPTION AND SURFACE DIFFUSION BY PULSED LASER TECHNIQUES. In American Chemical Society, Division of Petroleum Chemistry, Preprints (3 ed., Vol. 29, pp. 721). ACS.

STUDIES OF DESORPTION AND SURFACE DIFFUSION BY PULSED LASER TECHNIQUES. / Burgess, D.; Hussla, I.; Stair, Peter C; Viswanathan, R.; Weitz, E.

American Chemical Society, Division of Petroleum Chemistry, Preprints. Vol. 29 3. ed. ACS, 1984. p. 721.

Research output: Chapter in Book/Report/Conference proceedingConference contribution

Burgess, D, Hussla, I, Stair, PC, Viswanathan, R & Weitz, E 1984, STUDIES OF DESORPTION AND SURFACE DIFFUSION BY PULSED LASER TECHNIQUES. in American Chemical Society, Division of Petroleum Chemistry, Preprints. 3 edn, vol. 29, ACS, pp. 721.
Burgess D, Hussla I, Stair PC, Viswanathan R, Weitz E. STUDIES OF DESORPTION AND SURFACE DIFFUSION BY PULSED LASER TECHNIQUES. In American Chemical Society, Division of Petroleum Chemistry, Preprints. 3 ed. Vol. 29. ACS. 1984. p. 721
Burgess, D. ; Hussla, I. ; Stair, Peter C ; Viswanathan, R. ; Weitz, E. / STUDIES OF DESORPTION AND SURFACE DIFFUSION BY PULSED LASER TECHNIQUES. American Chemical Society, Division of Petroleum Chemistry, Preprints. Vol. 29 3. ed. ACS, 1984. pp. 721
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