Paper Number
AD5
Session
Active and Directed Systems
Title
Hydrodynamic coupling to the electrical response of fluid suspensions of non-Brownian conducting particles
Presentation Date and Time
October 23, 2019 (Wednesday) 3:45
Track / Room
Track 5 / Room 306A
Authors
- Richards, Jeffrey J. (Northwestern University, Chemical & Biological Engineering)
- Snell, Matthew (Northwestern University)
Author and Affiliation Lines
Jeffrey J. Richards and Matthew Snell
Chemical & Biological Engineering, Northwestern University, Evanston, IL 60203
Speaker / Presenter
Richards, Jeffrey J.
Text of Abstract
Here, we report on the electrical response of conducting non-Brownian suspensions to applied steady shear. These observations are made in a rheo-dielectric device that tracks the transient and steady electrical response of complex fluids to well-defined deformations. We show using dc-conductivity measurements a shear-rate dependent conductivity that increases both with the shear intensity and the particle volume fraction. The conductivity increases instantaneously upon flow start-up and returns instantaneously and reversibly to the quiescent value upon flow cessation. For volume fractions exceeding 30 vol% microspheres, the ratio of the conductivity under flow to that in the quiescent state can exceed a factor of 105. We further examine the origin of this increase using impedance spectroscopy. These measurements reveal a dielectric relaxation feature that is associated with the pair hopping rate of electrons between particles within the suspension. By fitting this dielectric response, a characteristic hopping time can be extracted that is linear with shear rate. These results agree quantitatively with a simple scaling model that approximates the pair-hopping rate of electrons as proportional to the collision frequency of particles within the suspension. This result confirms that the hydrodynamic forces imposed by simple shear couples to the interparticle charge transfer rate. In this way, the electrical response is directly linked to the displacement rate of the fluid. These observations help to reconcile emerging experimental evidence for the role of particle mobility in determining electrical transport in colloidal fluids and suspensions and could provide a basis for new mechano-electric sensing modalities as well as improved electrochemical storage technologies.