H21G-1466
Dynamics and mechanisms of asbestos-fiber aggregate growth in water

Tuesday, 15 December 2015
Poster Hall (Moscone South)
Lei Wu, University of Pennsylvania, Department of Earth and Environmental Science, Philadelphia, PA, United States, Carlos Pompeyo Ortiz, University of Pennsylvania, Philadelphia, PA, United States and Douglas J Jerolmack, Univ of PA-Earth &Envir Scienc, Philadelphia, PA, United States
Abstract:
Most colloidal particles including asbestos fibers form aggregates in water, when solution chemistry provides favorable conditions. To date, the growth of colloidal aggregates has been observed in many model systems under optical and scanning electron microscopy; however, all of these studies have used near-spherical particles. The highly elongated nature of asbestos fibers may cause anomalous aggregate growth and morphology, but this has never been examined. Although the exposure pathway of concern for asbestos is through the air, asbestos particles typically reside in soil that is at least partially saturated, and aggregates formed in the aqueous phase may influence the mobility of particles in the environment. Here we study solution-phase aggregation kinetics of asbestos fibers using a liquid-cell by in situ microscopy, over micron to centimeter length scales and from a tenth of a second to hours. We employ an elliptical particle tracking technique to determine particle trajectories and to quantify diffusivity. Experiments reveal that diffusing fibers join by cross linking, but that such linking is sometimes reversible. The resulting aggregates are very sparse and non-compact, with a fractal dimension that is lower than any previously reported value. Their morphology, growth rate and particle size distribution exhibit non-classical behavior that deviates significantly from observations of aggregates composed of near-spherical particles. We also perform experiments using synthetic colloidal particles, and compare these to asbestos in order to separate the controls of particle shape vs. material properties. This direct method for quantitatively observing aggregate growth is a first step toward predicting asbestos fiber aggregate size distributions in the environment. Moreover, many emerging environmental contaminants – such as carbon nanotubes – are elongated colloids, and our work suggests that theories for aggregate growth may need to be modified in order to model these particles.