Abstract:
This thesis presents measurements on kinetic energy of secondary
ions desorbed from surfaces by MeV ion bombardment. The aim of this
investigation is to get a deeper understanding of the mechanism of fast heavy ion
induced electronic sputtering from solid surfaces. An interesting feature of this
mechanism is its ability to eject intact, heavy, fragile and thermally labile
biomolecules into the gas phase. This effect has an exciting application in biological
mass spectrometry, as many compounds of biologically interest are difficult to ionize
and desorb into the gas phase without being fragmented. In fact, in the early
eightieth electronic sputtering was the only mass spectrometric ionization method to
study peptides and small proteins.
Since the discovery of fast heavy ion induced desorption, attempts
have been made to understand the mechanism behind the process. In the desorption
event, the ion formation mechanism may be different for different kinds of ions. The
molecules may be ionized directly in the ejection process or at a later stage in the gas
phase. The experimental observations related to the ionization process are limited in
the literature. An attempt to study this issue is carried out in the present study.
One of the physical parameters which is associated with the
desorption process is the kinetic energy gained by the secondary ions ejected from
the surface. In this study, a plasma desorption time-of-flight (TOF) mass
spectrometer (PDMS) has been employed to measure this energy distribution of
secondary ions, and the term 'initial axial energy distribution' is used throughout this
thesis instead of 'energy distribution' to differentiate it from (kinetic) energies gained
by secondary ions in the flight path of the mass spectrometer. Two independent
experimental methods to measure the initial axial energy distributions have been
developed using two types of TOF mass spectrometers, namely a linear type and a
reflectron type. In the linear method, the initial energy distributions are obtained
directly by converting the measured time distributions for the ions of interest. In the
reflectron method, the cut-off property of an ion mirror is used to make relative
measurements of the initial energy distribution. An analytical procedure has been
devised in order to extract the initial axial energy distributions with a high accuracy
for both positive and negative secondary ions. Mean value of the initial axial energy
of positive secondary ions of H+, H2+, 6Li+, 7Li+, Na+, and Cs+ thus measured are
found to be 4.9 eV, 4.8 eV, 1.1 eV, 1.3 eV, 1.5 eV and 3.3 eV respectively while the
negative secondary ions of H', OH*, and F* are found to be 0.6 eV, 0.9 eV and 1.1 eV
respectively. The experimental errors due to field leakage, a second order effect,
have been carefully examined and the necessary corrections have been made.
Several of measured energy distributions exhibit tails extending
towards energies lower than the corresponding acceleration potential in the TOF
mass spectrometer indicating an energy deficit. The degree of tailing depends upon
the nature of the desorbed ions. A fraction of the desorbed ions has thus less kinetic
energy than value expected from the acceleration voltage. This suggests the
possibility of a gas phase ion formation mechanism in fast heavy ion induced
desorption. By deconvoluting the converted energy distributions, which are obtained
from the experimental time distributions, it has been found that the measured initial
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axial energy distributions consist of two components; one component associated with
the desorption of secondary ions from the target surface, and the other with the ions
formed in the gas phase after the desorption event. The possibility of a separation of
ionisation events into these two categories is also theoretically examined in the
thesis. Using experimental observations, the time and place of ion formation of the
secondary ions are also suggested.
Analysis of the experimental results suggests that the initial axial
energy distributions of the secondary ions studied in the present work closely follow
a semi empirical function of the form E2exp(-E/E0), where Eo is a constant. This
indicates that the desorption mechanism of the studied secondary ions exhibits a
common ejection mechanism. This finding is in agreement with the experimental
results of the studies performed by varying the energy density of the primary ion
track (i.e. variation of the stopping power) while keeping the track dimensions
constant. The latter results showed a linear dependence of the full width at half
maximum (FWHM) of the initial axial energy distribution as a function of the
stopping power supporting some predictions described in a thermal desorption.