Nano-Fe mediated treatment of real hydraulic fracturing flowback and its practical implication on membrane fouling in tandem anaerobic-oxic membrane bioreactor
The rising water-use intensity, and lack of cost-effective treatment strategy and reuse of hydraulic fracturing flowback (HFF) has become an increasing cause of concern. The present work evaluates the integration of parallel sets of tandem anaerobic-oxic membrane bioreactor (AMBR) with and without n...
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sg-ntu-dr.10356-1437062020-09-18T00:51:23Z Nano-Fe mediated treatment of real hydraulic fracturing flowback and its practical implication on membrane fouling in tandem anaerobic-oxic membrane bioreactor Abass, Olusegun K. Zhang, Kaisong School of Civil and Environmental Engineering Engineering::Civil engineering Hydraulic Fracturing Flowback Membrane Bioreactor The rising water-use intensity, and lack of cost-effective treatment strategy and reuse of hydraulic fracturing flowback (HFF) has become an increasing cause of concern. The present work evaluates the integration of parallel sets of tandem anaerobic-oxic membrane bioreactor (AMBR) with and without nano-Fe for treatment and reuse of real HFF obtained from Ordos Basin, China. Treatment efficiencies in terms of organic conversions, micro-pollutants degradation, resource recovery, and effects of nano-Fe release on membrane fouling were evaluated. Nano-Fe mediated AMBR (FAMBR) system effectively reduce target micro-pollutants (such as Acenaphthylene) at 94.4 % compared to the parallel AMBR system (17.1 % without nano-Fe). Moreover, recovery of potential economic chemicals like Al and P (1.0 and 0.6 mg/g spent nano-Fe) availed using FAMBR system. However, colonization of FAMBR membrane surface by Fe-protein/peptide hydroxocomplexes initiated by Fe-catalyzed microbial extrusions present a huge fouling challenge relative to the AMBR system. Additional evidences from microscopic/spectroscopic analysis of the FAMBR membrane system revealed that despite having a promising outlook, mediation of nano-Fe with AMBR system might result in a major fouling event during HFF treatment. Engineered design of nano-Fe to reduced leached nano-Fe ions in pre-treatment step prior to AMBR treatment system may be of potential research consideration. O.K. Abass acknowledges a Presidential Postdoctoral Fellowship from Nanyang Technological University (NTU), Singapore, via Grant M4082326.030. K.S. Zhang acknowledges the support by funds from the Bureau of Frontier Sciences and Education (QYZDB-SSW-DQC044), and the Bureau of International Cooperation (132C35KYSB20160018), CAS. Authors are also grateful for funding support provided by Xiamen Municipality Bureau of Science and Technology (3502Z20193073) and Oxiamembrane Co. Ltd., China for supplying the membranes used in the study. We would like to acknowledge the Central Environmental Science and Engineering Laboratory, Nanyang Technological University, Singapore, for use of their testing facility. 2020-09-18T00:51:23Z 2020-09-18T00:51:23Z 2020 Journal Article Abass, O. K., & Zhang, K. (2020). Nano-Fe mediated treatment of real hydraulic fracturing flowback and its practical implication on membrane fouling in tandem anaerobic-oxic membrane bioreactor. Journal of Hazardous Materials, 395, 122666-. doi:10.1016/j.jhazmat.2020.122666 0304-3894 https://hdl.handle.net/10356/143706 10.1016/j.jhazmat.2020.122666 32315793 395 en M4082326.030 Journal of Hazardous Materials © 2020 Elsevier B.V. All rights reserved. |
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Engineering::Civil engineering Hydraulic Fracturing Flowback Membrane Bioreactor Abass, Olusegun K. Zhang, Kaisong Nano-Fe mediated treatment of real hydraulic fracturing flowback and its practical implication on membrane fouling in tandem anaerobic-oxic membrane bioreactor |
| description |
The rising water-use intensity, and lack of cost-effective treatment strategy and reuse of hydraulic fracturing flowback (HFF) has become an increasing cause of concern. The present work evaluates the integration of parallel sets of tandem anaerobic-oxic membrane bioreactor (AMBR) with and without nano-Fe for treatment and reuse of real HFF obtained from Ordos Basin, China. Treatment efficiencies in terms of organic conversions, micro-pollutants degradation, resource recovery, and effects of nano-Fe release on membrane fouling were evaluated. Nano-Fe mediated AMBR (FAMBR) system effectively reduce target micro-pollutants (such as Acenaphthylene) at 94.4 % compared to the parallel AMBR system (17.1 % without nano-Fe). Moreover, recovery of potential economic chemicals like Al and P (1.0 and 0.6 mg/g spent nano-Fe) availed using FAMBR system. However, colonization of FAMBR membrane surface by Fe-protein/peptide hydroxocomplexes initiated by Fe-catalyzed microbial extrusions present a huge fouling challenge relative to the AMBR system. Additional evidences from microscopic/spectroscopic analysis of the FAMBR membrane system revealed that despite having a promising outlook, mediation of nano-Fe with AMBR system might result in a major fouling event during HFF treatment. Engineered design of nano-Fe to reduced leached nano-Fe ions in pre-treatment step prior to AMBR treatment system may be of potential research consideration. |
| author2 |
School of Civil and Environmental Engineering |
| author_facet |
School of Civil and Environmental Engineering Abass, Olusegun K. Zhang, Kaisong |
| format |
Article |
| author |
Abass, Olusegun K. Zhang, Kaisong |
| author_sort |
Abass, Olusegun K. |
| title |
Nano-Fe mediated treatment of real hydraulic fracturing flowback and its practical implication on membrane fouling in tandem anaerobic-oxic membrane bioreactor |
| title_short |
Nano-Fe mediated treatment of real hydraulic fracturing flowback and its practical implication on membrane fouling in tandem anaerobic-oxic membrane bioreactor |
| title_full |
Nano-Fe mediated treatment of real hydraulic fracturing flowback and its practical implication on membrane fouling in tandem anaerobic-oxic membrane bioreactor |
| title_fullStr |
Nano-Fe mediated treatment of real hydraulic fracturing flowback and its practical implication on membrane fouling in tandem anaerobic-oxic membrane bioreactor |
| title_full_unstemmed |
Nano-Fe mediated treatment of real hydraulic fracturing flowback and its practical implication on membrane fouling in tandem anaerobic-oxic membrane bioreactor |
| title_sort |
nano-fe mediated treatment of real hydraulic fracturing flowback and its practical implication on membrane fouling in tandem anaerobic-oxic membrane bioreactor |
| publishDate |
2020 |
| url |
https://hdl.handle.net/10356/143706 |
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1681057088835420160 |