Field Distributions in Thin Water Films - A Comparison of Theoretical and Empirical Trends

Abstract

Field ionization of thin water layers adsorbed onto a platinum field emitter tip was investigated by numerical simulation and analysis of experimental data. The numerical simulation, which includes a field-dependent relative permittivity, was developed to predict the field distribution around a water- covered field emitter tip. The model predicts that the dominant field occurs at the water-vacuum inter- face in thin layers. In the experiments, water adlayers were grown under field-free conditions by exposure of a cryogenically cooled emitter tip to water vapor in ultrahigh vacuum. Field ionization was probed by ramped field desorption (RFD) in which desorption of ionic species (hydrated protons) is measured while increasing the applied electric field linearly in time. The onset field of ionization decreased from 0.3 to 0.2 V/A as temperature increased from 130 to 150 K. An activation barrier of 0.7 eV (16 kcal/mol) for ionization of water to produce hydrated protons and hydroxide ions was estimated from the temperature dependence of the onset field. The experimental trends agree with the predicted trends for thin water layers.

Document Details

Document Type

Technical Report

Publication Date

Jun 24, 1999

Accession Number

ADA365077

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