posted on 2023-08-14, 23:34authored byAki Goto, Koji Michishio, Toshitaka Oka, Masahito Tagawa, Shinichi Yamashita
Atomic oxygen (AO)
is one of the dominant components of the residual
atmosphere in low Earth orbit. AO collides with spacecraft with a
translational energy of 5 eV, forming nanoscale protrusions on polymeric
materials. To clarify the influences of a polymer’s chemical
structure on the formation of AO-induced microstructures, this study
investigated the size of free-volume holes and the layer thickness
that interacted with AO for polyethylene (PE), polypropylene (PP),
and polystyrene (PS) by positron annihilation lifetime spectroscopy.
The injection energies of positrons varied from 1.3 to 10 keV to adjust
the injection depth (range) into the polymers (40 nm–1.6 μm).
For the pristine films, the lifetime of ortho-positronium
(o-Ps, τ3) was longer in the order
of PS, PP, and PE regardless of the injection energy of positrons,
showing the different sizes of free-volume holes with radii of 0.29,
0.31, and 0.32 nm, respectively. The fraction of the decay component
corresponding to o-Ps in all decay components (relative
intensity of o-Ps, I3) was used to investigate the chemical change induced by AO exposure.
The I3 values for the three polymers were
decreased by AO exposure of (2–5) × 1018 atoms/cm2 or more at a depth of 40–48 nm, obtained by 1.3 keV
positrons. This indicates that AO formed polar groups (i.e., an oxidized
layer) on the polymer surfaces. The maximum depths of such chemical
change for PE and PP were deeper than that for PS. The different sizes
of free-volume holes would affect the diffusion or ballistic penetration
of AO, resulting in the difference in the oxidized layers’
thicknesses and surface morphologies.