Your search keyword '"Julie Dam Larsen"' showing total 4 results

1. Greenhouse gas emissions from the mineralisation process in a Sludge Treatment Reed Bed system: Seasonal variation and environmental impact

Author

Charlotte Scheutz, Julie Dam Larsen, and Steen Lykke Nielsen

Subjects

Environmental Engineering, 0208 environmental biotechnology, 02 engineering and technology, Nitrous oxide, 010501 environmental sciences, Management, Monitoring, Policy and Law, Seasonality, medicine.disease, Reed bed, 01 natural sciences, Methane, 020801 environmental engineering, chemistry.chemical_compound, chemistry, Environmental chemistry, Greenhouse gas, Carbon dioxide, medicine, Sewage sludge treatment, Environmental science, Sludge, 0105 earth and related environmental sciences, Nature and Landscape Conservation

Abstract

Greenhouse gas emission data from the mineralisation process in Sludge Treatment Reed Bed systems (STRB) are scarce. The aim of this study was to quantify the emission rates of carbon dioxide (CO 2 ), methane (CH 4 ) and nitrous oxide (N 2 O) and to investigate seasonal variations in order to estimate the annual greenhouse gas emission rate of the mineralisation process. The full-scale STRB at Helsinge wastewater treatment plant (WWTP) in Denmark was chosen as the study site. Gas emission rates were measured using static surface flux chambers. The measurements were carried out in October/November 2014, March/April 2015, June/July 2015 and January/February 2016. We found that the emission rates of all included gas species were significantly affected by season. For CO 2 and CH 4 , the highest emission rates were recorded in summer, being138 and 5.2 g m −2 d −1 , respectively, while the lowest rates were recorded in winter, being 442 and 0.7 g m −2 d −1 , respectively. For N 2 O, the highest and lowest rates were recorded in autumn and spring, being 0.47 and 0.31 g m −2 d −1 , respectively. Emissions of CO 2 and CH 4 appeared to be affected by changes in temperature, while N 2 O appeared to be affected not only by temperature, but also by the amount of precipitation. An annual greenhouse gas emission rate (given in CO 2 equivalents) of the mineralisation process was calculated for two scenarios based on the assumptions; 1) gas emission rates are not affected by the amount of sludge accumulated in the STRB and 2) gas emission rates are affected by the amount of sludge accumulated in the STRB. The results revealed that the annual global warming potential is to be found in a range between 7 and 13.4 kg CO 2 -eq·PE −1 y −1 .

Published

2017

2. Life cycle assessment comparing the treatment of surplus activated sludge in a sludge treatment reed bed system with mechanical treatment on centrifuge

Author

Marieke ten Hoeve, Steen Nielsen, Charlotte Scheutz, and Julie Dam Larsen

Subjects

Strategy and Management, 0208 environmental biotechnology, 02 engineering and technology, 010501 environmental sciences, Reed bed, 01 natural sciences, Industrial and Manufacturing Engineering, SDG 13 - Climate Action, SDG 7 - Affordable and Clean Energy, Life-cycle assessment, 0105 earth and related environmental sciences, General Environmental Science, Waste management, Renewable Energy, Sustainability and the Environment, business.industry, Fossil fuel, Stockpile, Building and Construction, Dewatering, 020801 environmental engineering, Activated sludge, Environmental science, Sewage sludge treatment, business, SDG 12 - Responsible Consumption and Production, Sludge

Abstract

In Denmark, the conventional method for treating sewage sludge is mechanical dewatering and subsequent storage. However, sludge treatment reed bed systems, which are holistic sludge treatment facilities combining the dewatering, mineralisation and storage of sludge, have been more common during the last three decades. Treatment of sludge in a sludge treatment reed bed system can be combined with post-treatment (further dewatering and mineralisation) on a stockpile area. This study aimed to compare the environmental performances of a mechanical sludge treatment method with the sludge treatment reed bed system strategy, using the life cycle assessment approach and a life cycle inventory based on newly generated data obtained from Danish reference facilities. The scenarios based on the different treatment methods were initiated by sludge entering the sludge treatment reed bed system or the centrifuge and terminated by land application of the final sludge product. The environmental impacts caused by the sludge treatment reed bed system strategy were comparable to or lower than those caused by the mechanical sludge treatment method. The impacts on climate change were the same for all the treatment scenarios; however, the conversion of organic carbon and nitrogen into gas species was more efficient in the sludge treatment reed bed system compared to mechanical treatment. Thus, mechanically treated sludge contained more nitrogen, causing higher nitrogen emissions (nitrous oxide, nitrate and ammonia) when applied on land. Furthermore, the impact of resource depletion was higher for mechanical dewatering due to a larger fossil fuel demand related to daily operation and longer transportation distances in this scenario. According to the results of the life cycle assessment, there were no considerable environmental gains made by combining the treatment of sludge in a sludge treatment reed bed system with post-treatment on a stockpile area. However, some practical aspects, which are not expressed in a life cycle assessment, should also be taken into consideration when evaluating the performances of sludge treatment scenarios.

Published

2018

3. Emissions of CO2 and CH4 from sludge treatment reed beds depend on system management and sludge loading

Author

Linda Olsson, Hans Brix, Julie Dam Larsen, and Siyuan Ye

Subjects

Air Pollutants, geography, Environmental Engineering, geography.geographical_feature_category, Sewage, Environmental engineering, Gas emissions, Wetland, General Medicine, Carbon Dioxide, Management, Monitoring, Policy and Law, Poaceae, Waste Disposal, Fluid, Dewatering, Substrate (marine biology), Methane, chemistry.chemical_compound, chemistry, Wetlands, Greenhouse gas, Carbon dioxide, Sewage sludge treatment, Environmental science, Waste Management and Disposal

Abstract

Sludge treatment reed beds (STRB) are considered as eco-friendly and sustainable alternatives to conventional sludge treatment methods, although little is known about greenhouse gas emissions from such systems. We measured CO2 and CH4 emissions and substrate characteristics in a STRB, an occasionally loaded sludge depot (SD) and a natural reed wetland (NW). The aim was to compare (i) emissions among the sites in relation to substrate characteristics and to compare (ii) emissions before and after sludge loading in the STRB. The STRB emitted twice as much CO2 (1200 mg m-2 h-1) as the SD, whereas the SD emitted four times more CH4 (2 mg m-2 h-1) than the STRB. The NW had the lowest emissions of both gases. The differences in gas emissions among the sites were primarily explained by differences in the availability of oxygen in the substrate. As a consequence of overloading and poor management, the SD had no vegetation and a poor dewatering capacity, which resulted in anaerobic conditions favoring CH4 emission. In contrast, the well-managed STRB had more aerobic conditions in the sludge residue resulting in low CH4 emission rates. We conclude that well-designed and well-managed STRBs have a low climate impact relative to conventional treatment alternatives, but that overloading and poor sludge management enhances the emissions of CH4. Sludge treatment reed beds (STRB) are considered as eco-friendly and sustainable alternatives to conventional sludge treatment methods, although little is known about greenhouse gas emissions from such systems. We measured CO2 and CH4 emissions and substrate characteristics in a STRB, an occasionally loaded sludge depot (SD) and a natural reed wetland (NW). The aim was to compare (i) emissions among the sites in relation to substrate characteristics and (ii) emissions before and after sludge loading in the STRB. The STRB emitted twice as much CO2 (1200 mg m(-2) h(-1)) as the SD, whereas the SD emitted four times more CH4 (2 mg m(-2) h(-1)) than the STRB. The NW had the lowest emissions of both gases. The differences in gas emissions among the sites were primarily explained by differences in the availability of oxygen in the substrate. As a consequence of overloading and poor management, the SD had no vegetation and a poor dewatering capacity, which resulted in anaerobic conditions favoring CH4 emission. In contrast, the well-managed STRB had more aerobic conditions in the sludge residue resulting in low CH4 emission rates. We conclude that well-designed and well-managed STRBs have a low climate impact relative to conventional treatment alternatives, but that overloading and poor sludge management enhances the emissions of CH4.

Published

2014

4. Nitrogen mineralisation and greenhouse gas emission from the soil application of sludge from reed bed mineralisation systems

Author

Lars Stoumann Jensen, Steen Lykke Nielsen, Georgios Bekiaris, Charlotte Scheutz, Julie Dam Larsen, Beatriz Gómez-Muñoz, and Sander Bruun

Subjects

Environmental Engineering, Nitrogen, chemistry.chemical_element, 010501 environmental sciences, Management, Monitoring, Policy and Law, Reed bed, 01 natural sciences, chemistry.chemical_compound, Soil, Fertilizers, Waste Management and Disposal, 0105 earth and related environmental sciences, Sewage, Environmental engineering, Agriculture, 04 agricultural and veterinary sciences, General Medicine, Nitrous oxide, Dewatering, Soil conditioner, chemistry, Environmental chemistry, Carbon dioxide, 040103 agronomy & agriculture, 0401 agriculture, forestry, and fisheries, Environmental science, Sewage sludge treatment, Sludge

Abstract

A sludge treatment reed bed system (STRB) is a technology used for dewatering and stabilising sewage sludge via assisted biological mineralisation, which creates a sludge residue suitable for use as fertiliser on agricultural land. We evaluated the effect of sludge residue storage time (stabilisation time) for three STRBs on soil N mineralisation and CO 2 and N 2 O emissions in soil. The experiment revealed that the N mineralisation rate and emissions of CO 2 and N 2 O decreased as a function of treatment time in the STRBs. Mixed sludge residue (sludge residue subjected to different treatment times) for the three STRBs resulted in N mineralisation rates similar to the sludge residue subjected to a shorter treatment time but lower N 2 O emissions similar to the values of the older sludge residue. This finding reveals that combining fresh and more stabilised sludge residue ensures high N availability and reduces N 2 O emissions when applied to land.

Published

2016