Abstract
AbstractQuantifying and characterizing suspended sediment is essential to successful monitoring and management of estuaries and coastal environments. To quantify suspended sediment, optical and acoustic backscatter instruments are often used. Optical backscatter systems are more sensitive to mud particles (<63 μm) and flocs, whereas acoustic backscatter systems are more responsive to larger sand grains (>63 μm). It is thus challenging to estimate the relative proportion of sand or mud in environments where both types of sediment are present. The suspended sediment concentration measured by these devices depends on the composition of that sediment, thus it is also difficult to confidently measure concentration with a single instrument when the composition varies and extensive calibration is not possible. The objective of this paper is to develop a methodology for characterizing the relative proportions of sand and mud in mixed sediment suspensions by comparing the response of simultaneous optical and acoustic measurements. We derive a sediment composition index (SCI) that is used to directly predict the relative fraction of sand in suspension. Here, we verify the theoretical response of these optical and acoustic instruments in laboratory experiments and successfully apply this approach to field measurements from Ameland ebb‐tidal delta (the Netherlands). Increasing sand content decreases SCI, which was verified in laboratory experiments. A reduction in SCI appears during more energetic conditions when sand resuspension is expected. Conversely, the SCI increases in calmer conditions when sand settles out, leaving behind mud. This approach provides crucial knowledge of suspended sediment composition in mixed sediment environments.
Highlights
The objective of this paper is to develop a methodology for characterizing the relative proportions of sand and mud in mixed sediment suspensions by comparing the response of simultaneous optical and acoustic measurements
Readings in volts are first normalized in equivalent NTU using an offset value in log space, so that their values are aligned in Experiments 1 and 2 for purely mud suspension conditions
Results from Experiment 1 for 100 μm sand (Figures 3a and 3c) show that the sensors’ response is linear in log10(OBS)/acoustic Doppler velocimeters (ADVs) SNR space. This is valid for a range of total sediment concentration, such that 10 log10(OBS) = SNR + sediment composition index (SCI), confirming the theoretical relationship (Equation 9)
Summary
The sediment composition at a given site may vary widely in both particle size and mineralogy (Flemming & Ziegler, 1995; Son et al, 2011; Winkelmolen & Veenstra, 1974). The resulting flocs vary widely in diameter (from 10 to 1,000 μm) and have relatively low densities (ρfloc = O(1,100 − 2,000 kg/m3)) with irregular shapes and lower settling velocities than sand The spatial distribution of these different types of sediment is a function of morphology, supply, and hydrodynamic conditions
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
