Phosphorus fractionation and protein content control chemical phosphorus removal from corn biorefinery streams

Aguiar, Samuel; Li, Yang; Zhang, Manying; Sharma, Navneet; Cusick, Roland D.

doi:10.1002/jeq2.20015

Cited by 4 publications

(9 citation statements)

References 34 publications

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“…P recovery from large WRRFs in the Midwest has a direct influence on the reduction of P discharge, while P recovery from the large corn biorefineries could reduce embedded P in livestock feed. In states like Iowa, Wisconsin, Minnesota, and Missouri with high livestock populations, the reduction of P at biorefineries could also decrease the risk of manure P losses to surface water due to the lower P content in biorefinery coproducts used in animal feeds. − The mismatch of manure N/P with crop N/P needs means that application of manure to meet crop N needs entails excessive application of P and thus aggravated P loss risk to surface waters . Decreasing the manure P content by reducing the amount of P fed to animals thereby stands to mitigate manure-based contributions to non-point source P losses, which in some watersheds of the US Corn Belt are thought to be the major driver …”

Section: Resultsmentioning

confidence: 99%

“…Although approximately 1.71 Gg of P as the fertilizer is applied annually to US croplands, nearly 0.54 Gg of P enters water bodies due to soluble and erosive losses . Recovery and agricultural reuse of P from wastewater and aqueous food processing streams can both reduce the amount of phosphate rock needed while also reducing the amount of P in livestock feed that would eventually be lost to water bodies from animal waste streams. − Outside of P recovery that is already done (e.g., land application of manure and wastewater sludge), human waste and animal manure present two main untapped pathways for renewable P (rP).…”

Section: Introductionmentioning

confidence: 99%

“…Animal waste has also been directly land applied as a means of nutrient recycling but is done to primarily meet nitrogen (N) needs, which can lead to overapplication of P. The environmental impacts associated with transportation are also higher for manure than concentrated rP products due to the excess weight of the organic matrix . An alternative to P recovery from manure is to recover P from highly concentrated biorefinery coproduct streams that are sold as animal feeds such as corn (Zea mays) gluten feed and distillers dried grains with solubles (DDGS), especially considering that the magnitude of P in maize and soybean milling coproducts is nearly equivalent to that of P in excess manure . Currently, this animal feed is fed to livestock and excreted as manure which may be overapplied and cause excessive P losses .…”

Section: Introductionmentioning

confidence: 99%

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Mapping the National Phosphorus Recovery Potential from Centralized Wastewater and Corn Ethanol Infrastructure

Ruffatto

Emaminejad

Juneja

et al. 2022

Environ. Sci. Technol.

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Anthropogenic discharge of excess phosphorus (P) to water bodies and increasingly stringent discharge limits have fostered interest in quantifying opportunities for P recovery and reuse. To date, geospatial estimates of P recovery potential in the United States (US) have used human and livestock population data, which do not capture the engineering constraints of P removal from centralized water resource recovery facilities (WRRFs) and corn ethanol biorefineries where P is concentrated in coproduct animal feeds. Here, renewable P (rP) estimates from plant-wide process models were used to create a geospatial inventory of recovery potential for centralized WRRFs and biorefineries, revealing that individual corn ethanol biorefineries can generate on average 3 orders of magnitude more rP than WRRFs per site, and all corn ethanol biorefineries can generate nearly double the total rP of WRRFs across the US. The Midwestern states that make up the Corn Belt have the largest potential for P recovery and reuse from both corn biorefineries and WRRFs with a high degree of co-location with agricultural P consumption, indicating the untapped potential for a circular P economy in this globally significant grain-producing region.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Mapping the National Phosphorus Recovery Potential from Centralized Wastewater and Corn Ethanol Infrastructure

Ruffatto

Emaminejad

Juneja

et al. 2022

Environ. Sci. Technol.

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“…Although the replacement of highly water-soluble phosphate fertilizers such as MAP by organic P-rich (55% of total P) phytin would be expected to entail lower soil extractable inorganic P, exacerbated by greater P demand with an increasing degree of phytin substitution, we did not detect differences in soil Mehlich-3 P (colorimetric) across the phytin substitution gradient (Figure S1). In addition, since there was more inorganic P in thin stillage (dry grind plants) than light steep (wet milling), the blend ratios identified in this study may not reflect phytin recovered from dry grind facilities or wet milling plants that use phytase (Aguiar et al, 2020).…”

Section: Crop Growth and P Uptakementioning

confidence: 87%

“…promote P mineralization or at least mitigate microbial immobilization of P by decreasing the organic C to P ratio of the fertilizer mixture input (Aguiar et al, 2020;Arenberg & Arai, 2019;Zhang et al, 2014). On the other hand, organic P mineralization can be driven by the microbial need for C (Spohn & Kuzyakow, 2013), raising the possibility that P may be biochemically but not biologically mineralized (Condron et al, 2005) from phytate due to microbial C demand.…”

Section: Core Ideasmentioning

confidence: 99%

Phytin recovered from grain distillation can serve as a phosphorus fertilizer for maize and soybean

Lee,

Hertzberger,

Juneja

et al. 2024

Soil Science Soc of Amer J

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Phosphorus (P) recovery from waste streams can increase food system P use efficiency while simultaneousl mitigating point source P losses. Phytin is a P‐rich waste product generated from maize grain biorefineries, largely located in the US Midwest. However, since the majority of P in phytin is organic, phytin‐P is likely to have limited crop availability in soil following application, as it must first be mineralized to orthophosphate‐P by soil phosphatases. To evaluate the fertilizer potential of phytin recovered from a maize wet milling plant and test hypothesized mechanisms of P mineralization, a five‐step gradient of phytin substitution for monoammonium phosphate (MAP) (0%, 25%, 50%, 75%, and 100% substitution) was evaluated for maize (Zea mays L.) and soybean (Glycine max L.) growth in a P‐deficient Aquic Argiudoll. Irrespective of crop species, aboveground biomass at end of vegetative growth (VT stage) was similar for up to 75% phytin substitution as MAP, but was 21% lower for maize and 49% for soybean when phytin was fully substituted for MAP. Soil microbial biomass carbon (C), nitrogen (N), and P, as well as activities of phosphomonoesterase and phosphodiesterase were invariant across the phytin substitution gradient, suggesting negligible mineralization of phytin P. Full substitution of MAP with phytin lowered soil microbial biomass C:N by 121% for maize and by 153% for soybean, and soil phosphatase activities per unit microbial biomass C were 24% higher under soybean. Our results indicate that phytin can be partially substituted for highly water‐soluble P fertilizers for the two major crop species of the US Midwest in which phytin waste generation is co‐located.

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Valorization of biorefinery residues for sustainable fertilizer production: a comprehensive review

Chojnacka

2023

Biomass Conv. Bioref.

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The management of biowaste and agricultural solid waste is gaining attention due to rising landfill disposal costs and the need for locally available agricultural feedstocks. The biorefinery concept aims to achieve zero waste through valorizing residues as fertilizers. Despite containing NPK macronutrients, residues may not promote plant growth due to limited nutrient availability and phytotoxic compounds. The production of valuable organic, mineral-organic, or mineral fertilizers with confirmed agronomic properties as marketable biorefinery products remains understudied. This comprehensive review broadens our understanding of fertilizer production in biorefineries, which complements the energy (thermal, biogas, biodiesel) and chemical compounds (e.g., succinic acid, propanediol, protein concentrates) that are also generated within biorefineries. It is among the first reviews to investigate the importance of valorizing biorefinery residues as fertilizers, emphasizing methods leading to commercial products and the rationale behind this process. The findings confirm that directly applying unprocessed residues to the soil does not fully exploit their value as by-products. This study contributes to the practical analysis of barriers (legal, chemical, biological, technological) and opportunities (rising prices and reduced global availability of mineral fertilizers) related to fertilizer production in the biorefining process.

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Phosphorus fractionation and protein content control chemical phosphorus removal from corn biorefinery streams

Cited by 4 publications

References 34 publications

Mapping the National Phosphorus Recovery Potential from Centralized Wastewater and Corn Ethanol Infrastructure

Mapping the National Phosphorus Recovery Potential from Centralized Wastewater and Corn Ethanol Infrastructure

Phytin recovered from grain distillation can serve as a phosphorus fertilizer for maize and soybean

Valorization of biorefinery residues for sustainable fertilizer production: a comprehensive review

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