SoR logo The Society of Rheology 85th Annual Meeting
October 13-17, 2013 - Montréal, Québec, Canada
View Paper Info and Abstract


SC43 


Suspensions and Colloids


A hexatic-to-disorder transition in colloidal assembly near electrodes: Stronger flow yields less order


October 17, 2013 (Thursday) 9:05


Track 1 / Westmount

(Click on name to view author profile)

  1. Dutcher, Cari S. (University of Minnesota, Mechanical Engineering)
  2. Woehl, Taylor J. (University of California, Davis, Chemical Engineering and Materials Science)
  3. Talken, Nick H. (University of California, Davis, Chemical Engineering and Materials Science)
  4. Ristenpart, William D. (University of California, Davis, Chemical Engineering and Materials Science)

(in printed abstract book)
Cari S. Dutcher1, Taylor J. Woehl2, Nick H. Talken2, and William D. Ristenpart2
1Mechanical Engineering, University of Minnesota, Minneapolis, MN 55455; 2Chemical Engineering and Materials Science, University of California, Davis, Davis, CA 95616


Dutcher, Cari S.


Colloids are known to form two-dimensional, hexagonal closed packed (HCP) crystals near electrodes in response to electrohydrodynamic (EHD) flow. Previous work by several groups has established that the strength of the EHD flow increases as the applied AC frequency decreases, suggesting that the driving force for crystallization should increase at lower frequencies. Here we report that the HCP crystals instead undergo an order-to-disorder transition at sufficiently low frequencies, despite the increase in the attractive EHD driving force. At large frequencies (~500 Hz), monodisperse suspensions of micron-scale particles are observed to arrange into planar HCP crystals, consistent with prior work. As the frequency is decreased below approximately 250 Hz, however, the crystalline structure transitions to randomly close packed (RCP) with an orientational order parameter of significantly less than one. The transition is reversible and second order with respect to frequency, and independent measurements of the EHD aggregation rate confirm that the EHD driving force is indeed higher at the lower frequencies. We present evidence that the order-disorder transition is instead caused by an increased particle diffusivity associated with a corresponding increase in the particle height over the electrode induced at lower frequencies. The observations reported here thus represent a rare instance of an electrically tunable HCP-to-RCP transition, with broad implications for the use of time-varying frequencies to facilitate annealing of planar colloidal crystals.