Location: Watershed Physical Processes Research
Title: Determining the relationship between algal activity and ultrasonic attenuationAuthor
CARPENTER, BRIAN - University Of Mississippi | |
GOODWILLER, BRADLEY - University Of Mississippi |
Submitted to: Meeting Abstract
Publication Type: Abstract Only Publication Acceptance Date: 4/20/2022 Publication Date: N/A Citation: N/A Interpretive Summary: Abstract only. Technical Abstract: A Single Frequency Acoustic Attenuation Surrogate was developed by NCPA to measure suspended sediment concentrations using 20 mega hertz acoustic signals. Previous work hypothesized that biological factors, such as population variation or algal movements, could also be determining factors in increasing acoustic signal attenuation when there is an absence of suspended sediment transport. This change in attenuation may occur in dense colonies because increasing light intensity leads to high photosynthetic rates during the day, which can produce oxygen bubbles within colonies that increase buoyancy and cause algal cells to rise in the water column. In contrast, respiration at night consumes oxygen bubbles, resulting in sinking algal colonies. To test this hypothesis, semi-controlled experiments in still water with large algae populations were initiated in conjunction with United States Department of Agriculture-Agriculture Research Service-National Sedimentation Laboratory. The Single Frequency Acoustic Attenuation Surrogate instrumentation was deployed at The University of Mississippi Biological Field Station to investigate the relationship between acoustic signal attenuation and algal activity. Ancillary measurements were also monitored including light intensity, dissolved oxygen, and water temperature in an environment without sediment transport. Cyanobacteria was the dominant algal group in the limno-corral, and vertical movement of cyanobacteria is modulated by changes in cell density, gas vesicles inside of cells, and gas bubbles between cells in dense colonies. Measurements of dissolved oxygen concentrations were made in attempt to determine if acoustic attenuation was related to diel patterns in dissolved oxygen providing a potential linkage between oxygen concentrations, light, algal biomass and acoustic attenuation. |