Environmental Performance of Nitrogen Recovery from Reject Water of Sewage Sludge Treatment Based on Life Cycle Assessment

Recovering and recycling nitrogen available in waste streams would reduce the demand for conventional fossil-based fertilizers and contribute toward food security. Based on life cycle assessment (LCA), this study aimed to evaluate the environmental performance of nitrogen recovery for fertilizer purposes from sewage sludge treatment in a municipal wastewater treatment plant (WWTP). Utilizing either air stripping or pyrolysis-derived biochar adsorbent, nitrogen was recovered from ammonium-rich reject streams generated during mechanical dewatering and thermal drying of anaerobically digested sewage sludge. A wide range of results was obtained between different scenarios and different impact categories. Biochar-based nitrogen recovery showed the lowest global warming potential with net negative GHG (greenhouse gas) emissions of −22.5 kt CO2,eq/FU (functional unit). Ammonia capture through air stripping caused a total GHG emission of 2 kt CO2,eq/FU; while in the base case scenario without nitrogen recovery, a slightly lower GHG emission of 0.2 kt CO2,eq/FU was obtained. This study contributes an analysis promoting the multifunctional nature of wastewater systems with integrated resource recovery for potential environmental and health benefits.

[1]  Petteri Peltola,et al.  A novel dual circulating fluidized bed technology for thermal treatment of municipal sewage sludge with recovery of nutrients and energy. , 2022, Waste management.

[2]  K. Moustakas,et al.  Management of biological sewage sludge: Fertilizer nitrogen recovery as the solution to fertilizer crisis. , 2022, Journal of environmental management.

[3]  Michael Child,et al.  Assessing the operational environment of a P2X plant from a climate point of view , 2022, Journal of Cleaner Production.

[4]  P. Gurian,et al.  Life cycle assessment and techno-economic analysis of nitrogen recovery by ammonia air-stripping from wastewater treatment. , 2022, The Science of the total environment.

[5]  LorettaY Li,et al.  An economic and global warming impact assessment of common sewage sludge treatment processes in North America , 2022, Journal of Cleaner Production.

[6]  Yajun Wu,et al.  Enhanced technology for sewage sludge advanced dewatering from an engineering practice perspective: A review. , 2022, Journal of environmental management.

[7]  A. Azapagic,et al.  Environmental sustainability of negative emissions technologies: A review , 2022, Sustainable Production and Consumption.

[8]  M. Pohořelý,et al.  Sewage sludge treatment methods and P-recovery possibilities: Current state-of-the-art. , 2022, Journal of environmental management.

[9]  T. Liu,et al.  Recovery of ammonium nitrate solution from urine wastewater via novel free nitrous acid (FNA)-mediated two-stage processes , 2022, Chemical Engineering Journal.

[10]  J. Bień,et al.  Analysis of Reject Water Formed in the Mechanical Dewatering Process of Digested Sludge Conditioned by Physical and Chemical Methods , 2022, Energies.

[11]  T. Astrup,et al.  Environmental performance of dewatered sewage sludge digestate utilization based on life cycle assessment. , 2021, Waste management.

[12]  L. Dvořák,et al.  Recovery of Spent Sulphuric Acid by Diffusion Dialysis Using a Spiral Wound Module , 2021, International journal of molecular sciences.

[13]  Jan Matuštík,et al.  Is application of biochar to soil really carbon negative? The effect of methodological decisions in Life Cycle Assessment. , 2021, The Science of the total environment.

[14]  J. Levänen,et al.  Assessing the Carbon Footprint of Biochar from Willow Grown on Marginal Lands in Finland , 2021, Sustainability.

[15]  Petteri Peltola,et al.  Integrating Pyrolysis or Combustion with Scrubbing to Maximize the Nutrient and Energy Recovery from Municipal Sewage Sludge , 2021, Recycling.

[16]  S. Freguia,et al.  Optimising nitrogen recovery from reject water in a 3-chamber bioelectroconcentration cell , 2021 .

[17]  H. Ngo,et al.  Life cycle assessment of sewage sludge treatment and disposal based on nutrient and energy recovery: A review. , 2021, The Science of the total environment.

[18]  V. Kočí,et al.  Combining Process Modelling and LCA to Assess the Environmental Impacts of Wastewater Treatment Innovations , 2021, Water.

[19]  Haiping Yang,et al.  Industrial biochar systems for atmospheric carbon removal: a review , 2021, Environmental Chemistry Letters.

[20]  A. Hallajisani,et al.  Production of bio-oil from sewage sludge: A review on the thermal and catalytic conversion by pyrolysis , 2020 .

[21]  E. Khan,et al.  Evaluating biochar and its modifications for the removal of ammonium, nitrate, and phosphate in water. , 2020, Water research.

[22]  S. Schwede,et al.  Post-pyrolysis treatments of biochars from sewage sludge and A. mearnsii for ammonia (NH4-n) recovery , 2020 .

[23]  Paul T. Williams,et al.  Thermochemical conversion of sewage sludge: A critical review , 2020 .

[24]  Yuping Xu,et al.  Pyrolysis of Municipal Sewage Sludge for Biofuel Production: A Review , 2020 .

[25]  Jan Matuštík,et al.  Life cycle assessment of biochar-to-soil systems: A review , 2020, Journal of Cleaner Production.

[26]  R. Zelm,et al.  Life cycle assessment of side stream removal and recovery of nitrogen from wastewater treatment plants , 2020, Journal of Industrial Ecology.

[27]  K. Lam,et al.  Life cycle assessment of nutrient recycling from wastewater: A critical review. , 2020, Water research.

[28]  J. Havukainen,et al.  Evaluation and techno-economic analysis of packed bed scrubber for ammonia recovery from drying fumes produced during the thermal drying of sewage sludge , 2020, E3S Web of Conferences.

[29]  C. Cerri,et al.  Biochar-based nitrogen fertilizers: Greenhouse gas emissions, use efficiency, and maize yield in tropical soils. , 2019, The Science of the total environment.

[30]  Qianqian Yin,et al.  Biochar produced from the co-pyrolysis of sewage sludge and walnut shell for ammonium and phosphate adsorption from water. , 2019, Journal of environmental management.

[31]  C. Sundberg,et al.  Prospective Life Cycle Assessment of Large-Scale Biochar Production and Use for Negative Emissions in Stockholm. , 2019, Environmental science & technology.

[32]  P. Tlustoš,et al.  High temperature-produced biochar can be efficient in nitrate loss prevention and carbon sequestration , 2019, Geoderma.

[33]  Yao Tang,et al.  Influence of pyrolysis temperature on production of digested sludge biochar and its application for ammonium removal from municipal wastewater , 2019, Journal of Cleaner Production.

[34]  M. Heinonen,et al.  RAVITA Technology - new innovation for combined phosphorus and nitrogen recovery. , 2018, Water science and technology : a journal of the International Association on Water Pollution Research.

[35]  C. Vaneeckhaute,et al.  Evaluation of sustainable scrubbing agents for ammonia recovery from anaerobic digestate. , 2018, Bioresource technology.

[36]  J. Havukainen,et al.  Possibilities for enhanced nitrogen recovery from digestate through thermal drying , 2018 .

[37]  J. Havukainen,et al.  Life cycle assessment of small-scale combined heat and power plant: environmental impacts of different forest biofuels and replacing district heat produced from natural gas , 2018 .

[38]  Y. Ok,et al.  Adsorption of ammonium in aqueous solutions by pine sawdust and wheat straw biochars , 2018, Environmental Science and Pollution Research.

[39]  Yi Wang,et al.  Thermochemical processing of sewage sludge to energy and fuel: Fundamentals, challenges and considerations , 2017 .

[40]  Jouni Havukainen,et al.  Influence of different factors in the life cycle assessment of mixed municipal solid waste management systems – A comparison of case studies in Finland and China , 2017 .

[41]  Peter A. Vanrolleghem,et al.  Nutrient Recovery from Digestate: Systematic Technology Review and Product Classification , 2017 .

[42]  J. Havukainen,et al.  Nitrogen release from mechanically dewatered sewage sludge during thermal drying and potential for recovery , 2017 .

[43]  M. Asof,et al.  Recovery of H2SO4 from spent acid waste using bentonite adsorbent , 2017 .

[44]  P. Lens,et al.  Recent advances in nutrient removal and recovery in biological and bioelectrochemical systems. , 2016, Bioresource technology.

[45]  P. Westerhoff,et al.  Recovery opportunities for metals and energy from sewage sludges , 2016, Bioresource Technology.

[46]  M. Huijbregts,et al.  Global spatially explicit CO2 emission metrics for forest bioenergy , 2016, Scientific Reports.

[47]  Stephen R. Smith,et al.  A critical review of nitrogen mineralization in biosolids-amended soil, the associated fertilizer value for crop production and potential for emissions to the environment. , 2016, The Science of the total environment.

[48]  Knut Conradsen,et al.  A global approach for sparse representation of uncertainty in Life Cycle Assessments of waste management systems , 2016, The International Journal of Life Cycle Assessment.

[49]  J. Horswell,et al.  Effect of Pine Waste and Pine Biochar on Nitrogen Mobility in Biosolids. , 2016, Journal of environmental quality.

[50]  J Keller,et al.  Platforms for energy and nutrient recovery from domestic wastewater: A review. , 2015, Chemosphere.

[51]  Lingying Zhao,et al.  Development and evaluation of a full-scale spray scrubber for ammonia recovery and production of nitrogen fertilizer at poultry facilities , 2015, Environmental technology.

[52]  Danielle D. Bellmer,et al.  Recent advances in utilization of biochar , 2015 .

[53]  N. El-Gendy,et al.  Bioethanol Production from Rice Straw Enzymatically Saccharified by Fungal Isolates, Trichoderma viride F94 and Aspergillus terreus F98 , 2014 .

[54]  Qiong Zhang,et al.  Energy-nutrients-water nexus: integrated resource recovery in municipal wastewater treatment plants. , 2013, Journal of environmental management.

[55]  A. Pawłowski,et al.  Life cycle assessment of two emerging sewage sludge-to-energy systems: evaluating energy and greenhouse gas emissions implications. , 2013, Bioresource technology.

[56]  Dominique Guyonnet,et al.  Quantifying uncertainty in LCA-modelling of waste management systems. , 2012, Waste management.

[57]  Roland W. Melse,et al.  Air scrubbing techniques for ammonia and odor reduction at livestock operations : review of on-farm research in the Netherlands , 2005 .

[58]  R. Kleijn,et al.  Numerical approaches towards life cycle interpretation five examples , 2001 .