Evaluating the Impact of Algal Biomass Augmentation on Primary Solids Fermentation and Associated Impacts of Fermenter Liquor on a Novel Post-Anoxic Enhanced Biological Phosphorus Removal Process

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Evaluating the Impact of Algal Biomass Augmentation on Primary Solids Fermentation and Associated Impacts of Fermenter Liquor on a Novel Post-Anoxic Enhanced Biological Phosphorus Removal Process

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Romenesko, Taylor. (2017-08). Evaluating the Impact of Algal Biomass Augmentation on Primary Solids Fermentation and Associated Impacts of Fermenter Liquor on a Novel Post-Anoxic Enhanced Biological Phosphorus Removal Process. Theses and Dissertations Collection, University of Idaho Library Digital Collections. https://www.lib.uidaho.edu/digital/etd/items/romenesko_idaho_0089n_11175.html

Title:: Evaluating the Impact of Algal Biomass Augmentation on Primary Solids Fermentation and Associated Impacts of Fermenter Liquor on a Novel Post-Anoxic Enhanced Biological Phosphorus Removal Process
Author:: Romenesko, Taylor
Date:: 2017-08
Embargo Remove Date:: 2017-12-22
Keywords:: Algae Ammonia Removal Biological Nutrient Removal BIOPHO Municipal Sludge Fermentation Volatile Fatty Acids (VFA)
Program:: Civil Engineering
Subject Category:: Civil engineering; Environmental engineering; Water resources management
Abstract:: Nitrogen (N) and phosphorus (P) must be removed from wastewater to sustain the water quality of receiving bodies. In this regard, algae can be utilized to achieve tertiary wastewater treatment, removing residual N and P; moreover, algae production creates opportunities to enhance overall water resource recovery facility productivity. Research evaluated an integrated fermenter-biological nutrient removal (BNR) process, integrating algae cultured on secondary effluent. It was hypothesized that algae recycled to the fermenter would increase volatile fatty acid (VFA) production. VFAs are critical for BNR stability; however, concurrent addition of N and P (from the algal biomass) could stress the BNR system. Surprisingly, addition of algae decreased VFA production and consumed ammonia, seemingly due to heterotrophic algae growth in the fermenter. Conversely, the BNR system realized no effect from the algal biomass recycling; P removal was consistent with and without algae, while less efficient nitrification but more efficient denitrification was realized.
Description:: masters, M.S., Civil Engineering -- University of Idaho - College of Graduate Studies, 2017-08
Major Professor:: Coats, Erik R.
Committee:: Colberg, Patricia J. S.; Moberly, James
Defense Date:: 2017-08
Identifier:: Romenesko_idaho_0089N_11175
Type:: Text
Format Original:: PDF
Format:: application/pdf

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