Recovery of Nitrous Oxide from Wastewater Treatment: Current Status and Perspectives

Duan, Haoran; Zhao, Yingfen; Koch, Konrad; Wells, George F.; Weißbach, M.; Yuan, Zhiguo; Liu, Ye

doi:10.1021/acsestwater.0c00140

Cited by 25 publications

(18 citation statements)

References 73 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…This knowledge, in turn, will support the design and establishment of new N 2 O mitigation strategies. In addition, investigations into catalytic off-gas treatment of N 2 O are essential ( Duan et al., 2021 ; Scherson et al., 2013 ). Such treatment will further reduce GHG emissions, and is even evaluated for its potential to generate energy, as for example in the coupled aerobic-anoxic nitrous decomposition operation (CANDO) process ( Scherson et al., 2014 ).…”

Section: Discussionmentioning

confidence: 99%

Successful year-round mainstream partial nitritation anammox: Assessment of effluent quality, performance and N2O emissions

et al. 2022

View full text Add to dashboard Cite

Section: Discussionmentioning

confidence: 99%

Successful year-round mainstream partial nitritation anammox: Assessment of effluent quality, performance and N2O emissions

et al. 2022

View full text Add to dashboard Cite

“…Compared to the removal of NO 3 – contaminants as N 2 , the transformation to NH 3 /NH 4 + and N 2 O recovers the N-nutrients and upgrades the energetic value of the reactive-nitrogen contaminant species. Aqueous NH 3 /NH 4 + can be reused as a fertilizer and/or oxidized to generate electricity in an ammonia fuel-cell, and gaseous NH 3 can be used as a fuel to generate heat and produce electricity. − Despite being a potent greenhouse gas, N 2 O is also a powerful oxidizer, especially for the combustion of rocket-fuel and biogas and for supercharging applications as it increases the energy released during the combustion of CH 4 by 37% as compared to using O 2 as an oxidizer. ,, In prior work, bioprocesses have demonstrated viable energy and resource recovery during wastewater denitrification through the formation of N 2 O by coupling N-removal to high-rate and high-efficiency N 2 O generation. ,,, …”

Section: Photoelectrochemical Device For Wastewater Nitrate Treatmentmentioning

confidence: 99%

“…This study focuses on evaluating the feasibility of a photoelectrochemical approach to recover nitrogen nutrients from NO 3 – contaminants present in ion-exchange brines − and treated wastewater. ,− The state-of-the-art nitrification-denitrification processes for wastewater treatment are biological approaches that utilize microbes to consume and remove the excess nutrients. , However, the conventional two-stage biological nitrification–denitrification process is energy intensive, consuming up to 45 MJ kg N –1 , − not effective in effluent streams that harbor conditions unsuitable for microbial growth, , and has not been optimized for resource recovery . Proof-of-concept bioprocesses, including the Sharon–Anammox and the coupled aerobic–anoxic nitrous decomposition operation (CANDO) have been proposed to lower the energy intensity and to promote energy recovery from N-contaminants but are yet to be adopted for large scale wastewater treatment. , Ion-exchange, ,, electrodialysis, , and reverse osmosis , are used to treat nitrates (and other ions) at an industrial scale for drinking water applications but result in the production of a secondary nitrate-concentrated brine that requires further treatment . Hence, there is an increasing demand to develop wastewater treatment technologies to harness renewable energy, to be effective for a wide range of effluent stream conditions and to facilitate resource recovery in the form of nutrients and energy.…”

Section: Introductionmentioning

confidence: 99%

“…12 Proof-of-concept bioprocesses, including the Sharon−Anammox and the coupled aerobic−anoxic nitrous decomposition operation (CANDO) have been proposed to lower the energy intensity and to promote energy recovery from N-contaminants but are yet to be adopted for large scale wastewater treatment. 23,26 Ion-exchange, 5,27,28 electrodialysis, 29,30 and reverse osmosis 31,32 nitrates (and other ions) at an industrial scale for drinking water applications but result in the production of a secondary nitrate-concentrated brine that requires further treatment. 33 Hence, there is an increasing demand to develop wastewater treatment technologies to harness renewable energy, to be effective for a wide range of effluent stream conditions and to facilitate resource recovery in the form of nutrients and energy.…”

Section: ■ Introductionmentioning

confidence: 99%

“…9,70,71 In prior work, bioprocesses have demonstrated viable energy and resource recovery during wastewater denitrification through the formation of N 2 O by coupling N-removal to high-rate and high-efficiency N 2 O generation. 9,10,26,72 While outside the scope of this work, product separation and collection for NH 3 /NH 4 + and N 2 O could pose significant challenges. Therefore, this aspect needs to be considered in the design and evaluation of practical devices.…”

Section: ■ Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Harnessing Photoelectrochemistry for Wastewater Nitrate Treatment Coupled with Resource Recovery

Barrera

Chandran

2021

ACS Sustainable Chem. Eng.

View full text Add to dashboard Cite

Wastewater is a misplaced resource well suited to recover nutrients, value-added chemicals, energy, and clean water. A photoelectrochemical device is proposed to transform wastewater nitrates to ammonia and nitrous oxide, coupled with water oxidation. Numerical models were developed to quantify the dependence of process efficiencies and nitrogen-removal rates on light absorber band gaps, electrocatalytic kinetic parameters, competing oxygen reduction and hydrogen evolution reactions, and the reacting nitrate species concentrations that affect the mass-transfer limited current densities. With a single light-absorber and state-of-the-art catalysts, optimal solar-to-chemical efficiencies of 7% and 10% and nitrogen-removal rates of 260 and 395 gN m -2 day -1 are predicted for nitrate reduction to ammonia and nitrous oxide respectively. The influence of competing reactions on the performance depends on the nitrate concentration and band gap of the light absorber modeled. Oxygen reduction is more dominant than hydrogen evolution to compete with the nitrate reduction reaction, but is mass-transfer limited. Even with kinetic parameters that enhanced the driving forces for the competing reactions, the performance is only minimally affected by these reactions for optimally selected band gaps and nitrate concentrations larger than 100 mM. Theoretically predicted peak nitrogen removal rates and specific energy intensities are competitive with reported estimates for bioelectrochemical and Sharon-Anammox processes for ammonia recovery and nitrogen removal respectively. This result, together with the added benefit of harnessing sunlight to produce value-added products, indicates promise in the photoelectrochemical approach as a tertiary pathway to recover nutrients and energy from wastewater nitrates.

show abstract

Strategies for ammonia recovery from wastewater: a review

Farghali,

Chen,

Osman

et al. 2024

Environ Chem Lett

View full text Add to dashboard Cite

The circular economy requires advanced methods to recycle waste matter such as ammonia, which can be further used as a fuel and a precursor of numerous value-added chemicals. Here, we review methods for the recovery of ammonia from wastewater with emphasis on biological and physicochemical techniques, and their applications. Biological techniques involve nitrification, denitrification, and anammox processes and the use of membrane bioreactors. Physicochemical techniques comprise adsorption, membrane filtration, ion exchange, chemical precipitation, ammonia stripping, electrochemical oxidation, photocatalytic oxidation, bioelectrochemical systems, and membrane hybrid systems. We found that nitrification and anammox processes in membrane bioreactors stand out for their cost-effectiveness, reduced sludge production, and energy efficiency. The use of struvite precipitation is an efficient, environmentally friendly, and recyclable method for ammonia removal. Membrane hybrid systems are promising for ammonia recovery, nutrient concentration, and wastewater treatment, with applications in fertilizer production and water purification. Overall, nitrogen removal ranges from 28 to 100%, and nitrogen recovery ranges from 9 to 100%.

show abstract

Recovery of Nitrous Oxide from Wastewater Treatment: Current Status and Perspectives

Cited by 25 publications

References 73 publications

Successful year-round mainstream partial nitritation anammox: Assessment of effluent quality, performance and N2O emissions

Successful year-round mainstream partial nitritation anammox: Assessment of effluent quality, performance and N2O emissions

Harnessing Photoelectrochemistry for Wastewater Nitrate Treatment Coupled with Resource Recovery

Strategies for ammonia recovery from wastewater: a review

Contact Info

Product

Resources

About