To explore the particle-size effect on craze plasticity and on the lev
el of toughening of high-impact polystyrene (HIPS), a commercial grade
HIPS (Mobil PS 4600) with a composite particle fraction of 0.217 and
average particle size of 2.51 mu m was used. The matrix fractions of t
he material were dissolved in toluene and the unaffected particles wer
e harvested as a gel fraction which was levitated in fresh toluene as
a dilute suspension. This dilute particle suspension was centrifuged t
o separate the particles into two non-overlapping small and large part
icle populations of average size 1.03 and 3.97 mu m, respectively. Wit
h these separated particles, two new blends of HIPS-type material with
narrow particle distributions were reconstituted using commercial gra
de Lustrex HH-104 PS, together with a reconstituted blend of HIPS made
up of the original broad particle-size distribution to be used as a s
tandard for comparison. All three blends had the same volume fraction
as the original HIPS. Stress-strain experiments performed on the recon
stituted blends showed that the mechanical properties and toughness le
vels of the reconstituted HIPS were nearly identical to the properties
of the original HIPS. While the toughness of the reconstituted materi
al with larger particles was roughly halved at the same flow stress le
vel, the flow stress of the reconstituted blend with small particles h
ad a craze flow stress 5% higher than that of the other two reconstitu
ted blends, and a very severely reduced level of toughness. The behavi
our of these blends was analysed with the aid of a theoretical model d
eveloped by Piorkowska et al. and furnished additional support for the
correctness of the particle-size effect based on the principle of 'st
ress-induced displacement misfit' proposed by Argon et al. previously.