Biopolymer Stabilization for Mine Tailings Dust Control Rui Chen (Graduate Student), Mark Gregory (Undergraduate Student), Lianyang Zhang (Advisor) Department of Civil Engineering and Engineering Mechanics, The University of Arizona BackgroundWhy Use Biopolymer?Preliminary Results (Cont.) Preliminary Results Preliminary Results (Cont.) Conclusions Research Approach The mining industry produces significant amount of mine tailings (MT) every year. Most of the MT are disposed of in on-site impoundments behind engineered earth and rock dams, which leads to different environmental and safety concerns. MT are susceptible to wind erosion, especially in arid and semiarid regions. The fugitive dust can reduce the visibility along nearby roads, degrade air quality in the vicinity, and contaminate soils and surface water. The failure of tailing dams or impoundments can cause large amount of contaminated liquid and slurry released into the environment, resulting in pollution and loss of lives and properties. Different methods have been attempted to stabilize MT in order to improve the impoundment stability and the erosion resistance. Ordinary Portland cement (OPC) has been used to stabilize tailings dams. However, OPC is an energy-intensive material and its production generates significant amount of carbon dioxide (CO 2 ). Conventional methods to reduce wind erosion includes using physical covers such as gravel, synthetic materials, or topsoil from nearby site, using chemical stabilizers such as lignin sulfonate or polyacrylamide copolymers (PMA), and phytostabilization by introducing particular plants. However, all these methods have limitations. For example, the transportation of soil from nearby site may be expensive or the soil may simply not be available. Chemical stabilizers are generally expensive and some of them may have negative impact on the environment. MT usually show acidic pH and contain no organic matter, making them unsuitable for plants growing. The physical covering and phytostabilization methods are only applicable to MT impoundments after closure. Therefore, there is an urgent need for developing an environmentally-friendly and cost-effective technology for stabilization of MT. At the University of Arizona, an extensive research program is being conducted on utilization of biopolymers to stabilize MT so that the impoundment stability and the erosion resistance are improved. Biopolymers are considered to be environmentally friendly because of their biodegradability and non-toxicity. The poster presents the preliminary results obtained so far.  Inclusion of either xanthan gum or guar gum increases the undrained shear strength of MT.  MT treated with xanthan gum or guar gum show obvious improvement in water retention capacity as indicated by the decreased speed of water loss.  MT treated with xanthan gum or guar gum show obvious improvement in dust resistance as indicated by the decreased weight loss of dry MT samples in the wind tunnel tests.  Biopolymer possesses long chains which form crosslinking networks bridging the MT particles; the presence of numerous hydroxyl groups and polar groups is beneficial to the formation of numerous hydrogen bonds and ionic bonds that strengthen the MT. Increase of Undrained Shear Strength Biopolymer concentration versus undrained shear strength at water content w = 30% and viscosity of biopolymer solution. Water retention properties of MT samples treated with xanthan gum, guar gum and soil-sement solution at different concentrations Wind Tunnel Tests Weight loss of dry MT samples treated with xanthan gum, guar gum and soil-sement solution at different concentrations ESEM Imaging Acknowledgement The research is supported by Freeport-McMoRan Copper & Gold Inc., Arizona. The Midwest Industrial Supply, Inc. provided the Soil-Sement sample used in this study. ESEM images of MT treated with (a) Guar gum; and (b) Xanthan gum innocuous (a)(b) Underlying Mechanisms of Improvement HO CH 2 O O O HO NH 2 O OH abundantly available Xanthan gum Guar gum Ionic bond Hydrogen bond MT particle Strength Tests Macro-Scale Study Wind Tunnel Tests Durability Tests Moisture Retention Tests ESEM Imaging Micro/Nano-Scale Study XRD Characterization AFM Nanoindentation BET Analysis DEM Simulations Development of a “Recipe” Water Retention Tests biodegradable