posted on 2019-10-25, 13:39authored byJaewon Lee, Sang Yup Lee, Dong-Kwon Lim, Dong June Ahn, Seungwoo Lee
Gold
(Au) colloids are becoming ubiquitous across biomedical engineering,
solar energy conversion, and nano-optics. Such universality has originated
from the exotic plasmonic effect of Au colloids (i.e., localized surface
plasmon resonance (LSPRs)) in conjunction with the versatile access
to their synthetic routes. Herein, we introduce a previously undiscovered
usage of Au colloids for advancing cryoprotectants with significant
ice recrystallization inhibition (IRI). Oligopeptides inspired by
the antifreeze protein (AFP) and antifreeze glycoprotein (AFGP) are
attached onto the surface of well-defined Au colloids with the same
sizes but different shapes. These AF(G)P-inspired Au colloids can
directly adsorb onto a growing ice crystal via the synergistic interplay
between hydrogen bonding and hydrophobic groups, in stark contrast
to their bare Au counterparts. Dark-field optical microscopy analyses,
benefiting from LSPR, allow us to individually trace the in situ movement
of the antifreezing Au colloids during ice growth/recrystallization
and clearly evidence their direct adsorption onto the growing ice
crystal, which is consistent with theoretical predictions. With the
assistance of molecular dynamics (MD) simulations, we evidently attribute
the IRI of AF(G)P-inspired Au colloids to the Kelvin effect. We also
exploit the IRI dependence on the Au colloidal shapes; indeed, the
facet contacts between ice and Au colloids can be better than the
point-like counterparts in terms of IRI. The design principles and
predictive theory outlined in this work will be of broad interest
not only for the fundamental exploration of the inhibition of ice
growth but also for enriching the application of Au colloids.