Quantifying the 3D structure and function of porosity and pore space in natural sediment flocs

Purpose Flocculated cohesive suspended sediments (flocs) play an important role in all aquatic environments, facilitating the transport and deposition of sediment and associated contaminants with consequences for aquatic health, material fluxes, and morphological evolution. Accurate modelling of the transport and behaviour of these sediments is critical for a variety of activities including fisheries, aquaculture, shipping, and waste and pollution management and this requires accurate measurement of the physical properties of flocs including porosity. Methods Despite the importance of understanding floc porosity, measurement approaches are indirect or inferential. Here, using mu CT, a novel processing and analysis protocol, we directly quantify porosity in natural sediment flocs. For the first time, the complexity of floc pore spaces is observed in 3-dimensions, enabling the identification and quantification of important pore space and pore network characteristics, namely 3D pore diameter, volume, shape, tortuosity, and connectivity. Results We report on the complexity of floc pore space and differentiate effective and isolated pore space enabling new understanding of the hydraulic functioning of floc porosity. We demonstrate that current methodological approaches are overestimating floc porosity by c. 30%. Conclusion These new data have implications for our understanding of the controls on floc dynamics and the function of floc porosity and can improve the parameterisation of current cohesive sediment transport models.

Automated summary

Flocculated cohesive suspended sediments (flocs) play a crucial role in aquatic environments, but accurate measurement of their physical properties, including porosity, is challenging. In this study, a novel processing and analysis protocol using μCT was employed to directly quantify porosity in natural sediment flocs. The results revealed the complexity of floc pore space and identified effective and isolated pore spaces, providing new insights into the hydraulic functioning of floc porosity. Current methodological approaches were found to overestimate floc porosity by approximately 30%.