posted on 2019-12-19, 18:38authored byDaniele Parisi, Yingbo Ruan, Guy Ochbaum, Kevin S. Silmore, Lucas L. Cullari, Chen-Yang Liu, Ronit Bitton, Oren Regev, James W. Swan, Benoit Loppinet, Dimitris Vlassopoulos
The yet virtually unexplored class of soft colloidal
rods with
a small aspect ratio is investigated and shown to exhibit a very rich
phase and dynamic behavior, spanning from liquid to nearly melt state.
Instead of the nematic order, these short and soft nanocylinders alter
their organization with increasing concentration from isotropic liquid
with random orientation to small domains with preferred local orientation
and eventually a multidomain arrangement with a local orientational
order. The latter gives rise to a kinetically suppressed state akin
to structural glass with detectable terminal relaxation, which, on
further increasing concentration, reveals features of hexagonally
packed order as in ordered block copolymers. The respective dynamic
response comprises four regimes, all above the overlapping concentration
of 0.02 g/mL:(I) from 0.03 to 0.1 g/mol, the system undergoes a liquid-to-solidlike
transition with a structural relaxation time that grows by 4 orders
of magnitude. (II) From 0.1 to 0.2 g/mL, a dramatic slowing-down is
observed and is accompanied by an evolution from isotropic to a multidomain
structure. (III) Between 0.2 and 0.6 g/mol, the suspensions exhibit
signatures of shell interpenetration and jamming, with the colloidal
plateau modulus depending linearly on concentration. (IV) At 0.74
g/mL, in the densely jammed state, the viscoelastic signature of hexagonally
packed cylinders from microphase-separated block copolymers is detected.
These properties set short and soft nanocylinders apart from long
colloidal rods (with a large aspect ratio) and provide insights for
fundamentally understanding the physics in this intermediate soft
colloidal regime and for tailoring the flow properties of nonspherical
soft colloids.