Photoionization and Photofragmentation of the Endohedral Xe@C60+ Molecular Ion
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Authors
Aryal, Nagendra B.
Issue Date
2013
Type
Dissertation
Language
Keywords
confinement resonances , endohedral , fullerene , interference , Photoionization
Alternative Title
Abstract
An experimental study of photoionization and fragmentation of the Xe@C60
+
endohedral molecular ion is presented in the photon energy range of the well-known Xe
4d giant resonance, and evidence of redistribution of the Xe 4d oscillator strength in
photon energy due to multipath interference is reported. Experiments were conducted at
undulator beamline 10.0.1 of the Advanced Light Source (ALS) using the merged-beams
technique. Prior to these measurements, macroscopic samples containing endohedral
Xe@C60 were prepared using a setup developed at the ALS. Endohedral Xe@C60 yields
as high as 2.5x10-4 were synthesized and a pure Xe@C60
+
ion beam current of up to 5.5
pA was obtained for the merged-beams experiments. Cross sections were measured in the
photon energy range 60 - 150 eV in 0.5 eV steps for single, double, and triple
photoionization of endohedral Xe@C60
+
accompanied by the loss of n pairs of carbon
atoms yielding Xe@C60-2n
2+ (n = 0, 1), Xe@C60-2n
3+ (n = 0, 1, 2, 3), and Xe@C58
4+ photoion products. Reference absolute cross-section measurements were made for empty C60
+
for the corresponding reaction channels. The spectroscopic measurements with Xe@C60
+
were placed onto an absolute scale by normalization to the reference cross sections for
C60
+
in ranges of photon energies where the Xe 4d contributions were negligible. Results
for single photoionization and fragmentation of Xe@C60
+ show no evidence of the
presence of the caged Xe atom. The measurements of double and triple photoionization
with fragmentation of Xe@C60
+
exhibit prominent signatures of the Xe 4d resonance and
together account for 6.6 ± 1.5 of the total Xe 4d oscillator strength of 10. Compared to
that for a free Xe atom, the Xe oscillator strength in Xe@C60
+
is redistributed in photon
ii
energy due to multipath interference of outgoing Xe 4d photoelectron waves that may be
transmitted or reflected by the spherical C60
+ molecular cage, yielding so-called
confinement resonances. The experimental data are compared with numerous theoretical
predictions for this novel single-molecule photoelectron interferometer system. The
comparison indicates that the interference structure is sensitive to the geometry of the
molecular cage.
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