Transformation of Organic Matter and the Emissions of Methane and Ammonia during Storage of Liquid Manure as Affected by Acidification

Sommer, Sven G.; Clough, Tim J.; Balaine, Nimlesh; Hafner, Sasha D.; Cameron, K. C.

doi:10.2134/jeq2016.10.0409

Cited by 40 publications

(38 citation statements)

References 36 publications

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“…At the end of the storage period, a decrease in the carbonate buffer was also observed in warmly stored slurries ( Figures 6-8). The resulting emissions depend on several factors such as storage temperature or the presence of an adapted microbial community in pre-stored slurry [48].…”

Section: Slurry Characterizationmentioning

confidence: 99%

Dynamics of Different Buffer Systems in Slurries Based on Time and Temperature of Storage and Their Visualization by a New Mathematical Tool

Overmeyer

Holtkamp

Clemens³

et al. 2020

Animals

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Simple Summary: Efficient slurry management is a key strategy to reduce the release of environmentally harmful gases produced by farm animals. Slurry treatments such as acidification and alkalization have proven to be promising solutions to reduce these emissions. In this context, it is crucial to understand how buffer capacities behave and may influence each other during storage under the influence of different temperatures. To realize this, we have developed and successfully verified a new mathematical tool. It allows an exact calculation and detailed visualization of the most important buffer systems found in the analyzed slurries. This knowledge can be used to optimize slurry treatments, as it allows faster, more precise and efficient timing of pH adjustment, thus, reducing the use of resources.Abstract: Slurry treatments such as acidification and alkalization have proven to be promising solutions to reduce gaseous emission produced by farm animals. The optimization of these technologies requires detailed knowledge of how and to what extent the buffer capacities in slurries will change during storage under the influence of different temperatures, as this may save resources needed to adjust a targeted pH value. Fresh slurries from dairy cows, fattening pigs and sows were collected and stored for 12 weeks under either cold (4.7 ± 1.1 • C) or warm (23.6 ± 2.1 • C) conditions to perform titrations in acidic and alkaline milieu at regular intervals. Based on these results, we successfully verified a new mathematical tool that we have developed to be able to calculate and visualize the most important buffer systems found in the analyzed slurries. Our experimental results showed a strong correlation between the degradation of the volatile fatty acid (VFA) buffer and the emergence of the carbonate buffers, i.e., the HCO 3 − and the CO 3 2− buffer. Furthermore, a drop in the pH value caused by enhanced microbial production of VFAs can be mitigated by the presence of the NH 3 buffer. In conclusion, we demonstrated that the buffers cannot be considered individually but must be interpreted as a complex and interacting system.

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Section: Slurry Characterizationmentioning

confidence: 99%

Dynamics of Different Buffer Systems in Slurries Based on Time and Temperature of Storage and Their Visualization by a New Mathematical Tool

Overmeyer

Holtkamp

Clemens³

et al. 2020

Animals

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“…The large volumes of manure produced annually from intensive dairy farming operations areusually stored in slurry form ( VanderZaag et al, 2013 ), which create environments conducive to CH 4 production ( Grant et al, 2015 ; Petersen, 2018 ). To reduce CH 4 emissions from such storage systems, strategies such as reduction of aged manure (inoculants), crust development for potential aerobic CH 4 oxidation, and manure acidification using sulfuric acid (H 2 O 4 ) have been reported ( Petersen et al, 2012 ; Sommer et al, 2017 ; Habtewold et al, 2018 ). Sulfuric acid-based acidification of liquid dairy manure has primarily been used to abate ammonia (NH 3 ) emissions, but can also reduce CH 4 emissions ( Ottosen et al, 2009 ; Petersen et al, 2012 ; Fangueiro et al, 2015 ; Sommer et al, 2017 ).…”

Section: Introductionmentioning

confidence: 99%

“…To reduce CH 4 emissions from such storage systems, strategies such as reduction of aged manure (inoculants), crust development for potential aerobic CH 4 oxidation, and manure acidification using sulfuric acid (H 2 O 4 ) have been reported ( Petersen et al, 2012 ; Sommer et al, 2017 ; Habtewold et al, 2018 ). Sulfuric acid-based acidification of liquid dairy manure has primarily been used to abate ammonia (NH 3 ) emissions, but can also reduce CH 4 emissions ( Ottosen et al, 2009 ; Petersen et al, 2012 ; Fangueiro et al, 2015 ; Sommer et al, 2017 ). For instance, CH 4 emissions from cattle slurry were reduced by 68% by acidification to pH 5.5 with H 2 SO 4 ( Sommer et al, 2017 ).…”

Section: Introductionmentioning

confidence: 99%

Reduction in Methane Emissions From Acidified Dairy Slurry Is Related to Inhibition of Methanosarcina Species

et al. 2018

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Liquid dairy manure treated with sulfuric acid was stored in duplicate pilot-scale storage tanks for 120 days with continuous monitoring of CH4 emissions and concurrent examination of changes in the structure of bacterial and methanogenic communities. Methane emissions were monitored at the site using laser-based Trace Gas Analyzer whereas quantitative real-time polymerase chain reaction and massively parallel sequencing were employed to study bacterial and methanogenic communities using 16S rRNA and methyl-coenzyme M Reductase A (mcrA) genes/transcripts, respectively. When compared with untreated slurries, acidification resulted in 69–84% reductions of cumulative CH4 emissions. The abundance, activity, and proportion of bacterial communities did not vary with manure acidification. However, the abundance and activity of methanogens (as estimated from mcrA gene and transcript copies, respectively) in acidified slurries were reduced by 6 and 20%, respectively. Up to 21% reduction in mcrA transcript/gene ratios were also detected in acidified slurries. Regardless of treatment, Methanocorpusculum predominated archaeal 16S rRNA and mcrA gene and transcript libraries. The proportion of Methanosarcina, which is the most metabolically-diverse methanogen, was the significant discriminant feature between acidified and untreated slurries. In acidified slurries, the relative proportions of Methanosarcina were ≤ 10%, whereas in untreated slurries, it represented up to 24 and 53% of the mcrA gene and transcript libraries, respectively. The low proportions of Methanosarcina in acidified slurries coincided with the reductions in CH4 emissions. The results suggest that reduction of CH4 missions achieved by acidification was due to an inhibition of the growth and activity of Methanosarcina species.

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“…Wooden covers can reduce CH 4 emissions more than a natural crust, though may have the potential to increase N 2 O emissions [36]. Manure acidification is another option for reducing emissions in liquid and anaerobic systems [37], with one recent study finding a 68% reduction [38]. Manure aeration or temperature reductions can also offer GHG mitigation opportunities [8], potentially up to 20% [9].…”

Section: Comprehensive Strategies To Promote Environmentally Sustainamentioning

confidence: 99%

Tradeoffs in US dairy manure greenhouse gas emissions, productivity, climate, and manure management strategies

Niles

Wiltshire

2019

Environ. Res. Commun.

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The United States is the largest supplier of dairy products globally, making it an important focus for environmental, economic, and societal outcomes. Increasingly greenhouse gases (GHGs) have become an area of focus for the industry, as industry groups have set their own goals to improve environmental impacts. A significant portion of dairy GHG emissions come from manure management, which can vary considerably by farm and region. Here we explore how the adoption and use of six common manure management strategies (MMS) have changed over a recent 12-year period, and how this relates to milk production, climate, and manure GHGs. Using data from the United States Department of Agriculture, the Environmental Protection Agency, and the National Oceanic and Atmospheric Administration across all fifty states, we find that overall US dairy manure management GHG emission intensity (CO 2 e per kg of milk produced) has increased 18% between 2003 and 2014, which is associated with an increase in adoption of liquid and anaerobic MMS. However, we also find that these systems are positively associated with higher productivity: nationally, total milk production grew by 21.0%, while the cow herd inventory grew by just 1.9%, an increase of 18.7% in per-cow milk production over the study period. We find clear regional adoption of certain kinds of MMS, which relate in many cases to temperature and rainfall. We discuss why these shifts may have occurred as a result of economic and policy drivers, including the shift towards these MMS for compliance with new water quality policies in the past decade, highlighting the tradeoffs that exist in on-farm decisionmaking. We provide some potential strategies to reduce GHG emissions in these systems while simultaneously considering water quality and other potential tradeoffs. We suggest that transitioning to some of these strategies requires additional research to better understand farmer decision-making as it relates to MMS, a currently understudied topic.

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Transformation of Organic Matter and the Emissions of Methane and Ammonia during Storage of Liquid Manure as Affected by Acidification

Cited by 40 publications

References 36 publications

Dynamics of Different Buffer Systems in Slurries Based on Time and Temperature of Storage and Their Visualization by a New Mathematical Tool

Dynamics of Different Buffer Systems in Slurries Based on Time and Temperature of Storage and Their Visualization by a New Mathematical Tool

Reduction in Methane Emissions From Acidified Dairy Slurry Is Related to Inhibition of Methanosarcina Species

Tradeoffs in US dairy manure greenhouse gas emissions, productivity, climate, and manure management strategies

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