Advanced search
Publication Cover
Environmental Technology Volume 45, 2024 - Issue 3
Submit an article Journal homepage
249
Views
2
CrossRef citations to date
0
Altmetric
Articles

Effects of pH on simultaneous Cr(VI) and p-chlorophenol removal and electrochemical performance in Leersia hexandra constructed wetland-microbial fuel cell

Yian Wanga College of Environmental Science and Engineering, Guilin University of Technology, Guilin, People’s Republic of China;b Guangxi Collaborative Innovation Center for Water Pollution Control and Water Safety in Karst Areas, Guilin University of Technology, Guilin, People’s Republic of ChinaORCID Iconhttps://orcid.org/0000-0003-2133-5363View further author information
ORCID Icon,
Xuehong Zhanga College of Environmental Science and Engineering, Guilin University of Technology, Guilin, People’s Republic of China;b Guangxi Collaborative Innovation Center for Water Pollution Control and Water Safety in Karst Areas, Guilin University of Technology, Guilin, People’s Republic of ChinaView further author information
&
Hua Lina College of Environmental Science and Engineering, Guilin University of Technology, Guilin, People’s Republic of China;b Guangxi Collaborative Innovation Center for Water Pollution Control and Water Safety in Karst Areas, Guilin University of Technology, Guilin, People’s Republic of ChinaCorrespondence[email protected]
View further author information
Pages 483-494 | Received 12 Mar 2022, Accepted 07 Aug 2022, Published online: 25 Aug 2022

References

  • Zhao S, Liu P, Niu YY, et al. A novel early warning system based on a sediment microbial fuel cell for in situ and real time hexavalent chromium detection in industrial wastewater. Sensors. 2018;18:642.
  • China MoEaEotPsRo. Environmental statistical annual report. Beijing: China Statistical Publishing House; 2015.
  • Ghaedrahmat Z, Moussavi M, Jorfi S, et al. Enhanced photocatalytic degradation of 4-chlorophenol using lanthanum oxide nano-particles under UVC/Vis irradiation. J Nanostruct. 2021;11:165–180.
  • Zanta CLPS, Michaud PA, Comninellis C, et al. Electrochemical oxidation of p-chlorophenol on SnO2-Sb2O5 based anodes for wastewater treatment. J Appl Electrochem. 2003;33:1211–1215.
  • Hidalgo AM, León G, Gómez M, et al. Application of the spiegler-kedem-kachalsky model to the removal of 4-chlorophenol by different nanofiltration membranes. Desalination. 2013;315:70–75.
  • Yazdanbakhsh A, Aliyari A, Sheikhmohammadi A, et al. Application of the enhanced sono-photo-Fenton-like process in the presence of persulfate for the simultaneous removal of chromium and phenol from the aqueous solution. J Water Process Eng. 2020;34:101080.
  • Mojiri A, Ahmad Z, Tajuddin RM, et al. Ammonia, phosphate, phenol, and copper(II) removal from aqueous solution by subsurface and surface flow constructed wetland. Environ Monit Assess. 2017;189:337.
  • Dotro G, Larsen D, Palazolo P. Treatment of chromium-bearing wastewaters with constructed wetlands. Water Environ J. 2011;25:241–249.
  • Wang C, Tan H, Li H, et al. Mechanism study of chromium influenced soil remediated by an uptake-detoxification system using hyperaccumulator, resistant microbe consortium, and nano iron complex. Environ Pollut. 2020;257:113558.
  • Liu J, Zhang XH, You SH, et al. Function of Leersia hexandra Swartz in constructed wetlands for Cr(VI) decontamination: a comparative study of planted and unplanted mesocosms. Ecol Eng. 2015;81:70–75.
  • Gu HY, Zhang XW, Li ZJ, et al. Studies on treatment of chlorophenol-containing wastewater by microbial fuel cell. Chin Sci Bull. 2007;52:3448–3451.
  • Sindhuja M, Harinipriya S, Bala AC, et al. Environmentally available biowastes as substrate in microbial fuel cell for efficient chromium reduction. J Hazard Mater. 2018;355:197–205.
  • Wang L, Xu D, Zhang Q, et al. Simultaneous removal of heavy metals and bioelectricity generation in microbial fuel cell coupled with constructed wetland: an optimization study on substrate and plant types. Environ Sci Pollut Res. 2022;29:768–778.
  • Li H, Song HL, Yang XL, et al. A continuous flow MFC-CW coupled with a biofilm electrode reactor to simultaneously attenuate sulfamethoxazole and its corresponding resistance genes. Sci Total Environ. 2018;637-638:295–305.
  • Cao X, Zhang S, Wang H, et al. Azo dye as part of co-substrate in a biofilm electrode reactor-microbial fuel cell coupled system and an analysis of the relevant microorganisms. Chemosphere. 2019;216:742–748.
  • Luo HP, Liu GL, Zhang RD, et al. Phenol degradation in microbial fuel cells. Chem Eng J. 2009;147:259–264.
  • Jadhav GS, Ghangrekar MM. Performance of microbial fuel cell subjected to variation in pH, temperature, external load and substrate concentration. Bioresour Technol. 2009;100:717–723.
  • Huang LP, Chai XL, Cheng SA, et al. Evaluation of carbon-based materials in tubular biocathode microbial fuel cells in terms of hexavalent chromium reduction and electricity generation. Chem Eng J. 2011;166:652–661.
  • Wang JF, Song XS, Wang YH, et al. Nitrate removal and bioenergy production in constructed wetland coupled with microbial fuel cell: establishment of electrochemically active bacteria community on anode. Bioresour Technol. 2016;221:358–365.
  • Crossley MN. The effects of water flow, pH and nutrition on the growth of the native aquatic plant, Aponogeton elongatus. Queensland: The University of Queensland; 2002.
  • Dziwulska-Hunek A, Ćwintal M, Niemczynowicz A, et al. Effect of stress caused by electromagnetic stimulation on the fluorescence lifetime of chlorophylls in alfalfa leaves. Pol J Environ Stud. 2019;28:3133–3143.
  • Yang Y, Zhao YQ, Tang C, et al. Dual role of macrophytes in constructed wetland-microbial fuel cells using pyrrhotite as cathode material: a comparative assessment. Chemosphere. 2021;263:128354.
  • Jin QS, Kirk MF. Ph as a primary control in environmental microbiology: 1. thermodynamic perspective. Front Environ Sci. 2018;6:21.
  • Wang YA, Zhang XH, Lin H. Removal of Cr(VI) and p-chlorophenol and generation of electricity using constructed wetland-microbial fuel cells based on Leersia hexandra Swartz: p-chlorophenol concentration and hydraulic retention time effects. RSC Adv. 2022;12:15123–15132.
  • Liu ST, Song HL, Wei SZ, et al. Bio-cathode materials evaluation and configuration optimization for power output of vertical subsurface flow constructed wetland-microbial fuel cell systems. Bioresour Technol. 2014;166:575–583.
  • Liu J, Duan CQ, Zhang XH, et al. Potential of Leersia hexandra Swartz for phytoextraction of Cr from soil. J Hazard Mater. 2011;188:85–91.
  • Doherty L, Zhao XH, Zhao YQ, et al. The effects of electrode spacing and flow direction on the performance of microbial fuel cell-constructed wetland. Ecol Eng. 2015;79:8–14.
  • Miran W, Nawaz M, Jang J, et al. Chlorinated phenol treatment and in situ hydrogen peroxide production in a sulfate-reducing bacteria enriched bioelectrochemical system. Water Res. 2017;117:198–206.
  • Raychaudhuri A, Behera M. Ceramic membrane modified with rice husk ash for application in microbial fuel cells. Electrochim Acta. 2020;363:137261.
  • Noor NM, Othman R, Mohd. Hatta MA, et al. Determination of linear Tafel region from piecewise linear regression analysis. Int J Electroact Mater. 2014;2:22–27.
  • Udosen ED, Benson NU, Essien JP, et al. Relation between aqua-regia extractable heavy metals in soil and manihot utilissima within a municipal dumpsite. Int J Soil Sci. 2006;1:27–32.
  • Seyrek UA, Luo M, Zhong M, et al. Effects of stored pollens from wild Actinidia eriantha vines on some fruit quality traits. Agric Sci. 2017;8:465–478.
  • Zargoosh Z, Ghavam M, Bacchetta G, et al. Effects of ecological factors on the antioxidant potential and total phenol content of Scrophularia striata Boiss. Sci Rep. 2019;9:16021.
  • Msimbira LA, Smith DL. The roles of plant growth promoting microbes in enhancing plant tolerance to acidity and alkalinity stresses. Front Sustainable Food Syst. 2020;4:106.
  • Sundberg C. Improving compost process efficiency by controlling aeration, temperature and pH. Uppsala: Swedish University of Agricultural Sciences; 2005.
  • Wiegand C, Abel M, Ruth P, et al. Ph influence on antibacterial efficacy of common antiseptic substances. Skin Pharmacol Physiol. 2015;28:147–158.
  • Srivastava P, Abbassi R, Kumar Yadav A, et al. Enhanced chromium(VI) treatment in electroactive constructed wetlands: influence of conductive material. J Hazard Mater. 2020;387:121722.
  • Zhang XL, Li XJ, Zhao XD, et al. Factors affecting the efficiency of a bioelectrochemical system: a review. RSC Adv. 2019;9:19748–19761.
  • Xu H, Song HL, Singh RP, et al. Simultaneous reduction of antibiotics leakage and methane emission from constructed wetland by integrating microbial fuel cell. Bioresour Technol. 2021;320:124285.
  • Lehl HK, Ong SA, Ho LN, et al. Multiple aerobic and anaerobic baffled constructed wetlands for simultaneous nitrogen and organic compounds removal. Desalin Water Treat. 2016;57:29160–29167.
  • Jung S, Regan JM. Comparison of anode bacterial communities and performance in microbial fuel cells with different electron donors. Appl Microbiol Biotechnol. 2007;77:393–402.
  • Ahmed B, Tyagi S, Rahmani AM, et al. Novel insight on ferric ions addition to mitigate recalcitrant formation during thermal-alkali hydrolysis to enhance biomethanation. Sci Total Environ. 2022;829:154621.
  • Heakal F E-T, Abd-Ellatif WR, Tantawy NS, et al. Impact of pH and temperature on the electrochemical and semiconducting properties of zinc in alkaline buffer media. RSC Adv. 2018;8:3816–3827.
  • Waegele MM, Gunathunge CM, Li JY, et al. How cations affect the electric double layer and the rates and selectivity of electrocatalytic processes. J Chem Phys. 2019;151:160902.
  • Yong XY, Gu DY, Wu YD, et al. Bio-Electron-Fenton (BEF) process driven by microbial fuel cells for triphenyltin chloride (TPTC) degradation. J Hazard Mater. 2017;324:178–183.
  • Yu YF, Ali J, Yang YS, et al. Synchronous Cr(VI) remediation and energy production using microbial fuel cell from a subsurface environment: a review. Energ. 2022;15:1989.
  • Jiang B, Wang XL, Hu P, et al. Dual enhancement-inhibition roles of polycarboxylates in Cr(VI) reduction and organic pollutant oxidation in electrical plasma system. Chemosphere. 2016;144:1611–1617.
  • Jiang B, Guo JB, Wang ZH, et al. A green approach towards simultaneous remediations of chromium(VI) and arsenic(III) in aqueous solution. Chem Eng J. 2015;262:1144–1151.
  • Milh H, Van Eyck K, Dewil R. Degradation of 4-chlorophenol by microwave-enhanced advanced oxidation processes: kinetics and influential process parameters. Water (Basel). 2018;10:247.
  • Yin XC, Liu W, Ni JR. Removal of coexisting Cr(VI) and 4-chlorophenol through reduction and Fenton reaction in a single system. Chem Eng J. 2014;248:89–97.
  • Rizvi A, Zaidi A, Ameen F, et al. Heavy metal induced stress on wheat: phytotoxicity and microbiological management. RSC Adv. 2020;10:38379–38403.
  • Mu CX, Wang L, Wang L. Removal of Cr(VI) and electricity production by constructed wetland combined with microbial fuel cell (CW-MFC): influence of filler media. J Cleaner Prod. 2021;320:128860.
  • Li H, Xu H, Song HL, et al. Antibiotic resistance genes, bacterial communities, and functions in constructed wetland-microbial fuel cells: responses to the co-stresses of antibiotics and zinc. Environ Pollut. 2020;265:115084.
  • Yan J, Hu XB, He Q, et al. Simultaneous enhancement of treatment performance and energy recovery using pyrite as anodic filling material in constructed wetland coupled with microbial fuel cells. Water Res. 2021;201:117333.
  • Wang JF, Song XS, Li QS, et al. Bioenergy generation and degradation pathway of phenanthrene and anthracene in a constructed wetland-microbial fuel cell with an anode amended with nZVI. Water Res. 2019;150:340–348.
  • Fang Z, Cheng SC, Wang H, et al. Feasibility study of simultaneous azo dye decolorization and bioelectricity generation by microbial fuel cell-coupled constructed wetland: substrate effects. RSC Adv. 2017;7:16542–16552.
  • Fang Z, Song HL, Yu R, et al. A microbial fuel cell-coupled constructed wetland promotes degradation of azo dye decolorization products. Ecol Eng. 2016;94:455–463.
  • Tarrahi R, Movafeghi A, Khataee A, et al. Evaluating the toxic impacts of cadmium selenide nanoparticles on the aquatic plant Lemna minor. Mol. 2019;24:410.
  • Asem ID, Imotomba R, Mazumder PB. The deep purple color and the scent are two great qualities of the black scented rice (chakhao) of Manipur. London, UK: IntechOpen; 2017.
  • Panhwar M, Jatoi G, Jilani G, et al. Exogenous hydrogen peroxide (H2O2) eustress to wheat genotypes attenuates their salinity distress. Int J Emerging Technol. 2021;12:258–269.
  • Yoon IK, Kim MJ, Min CW, et al. Effect of silicon application on growth response of alfalfa seedlings grown under aluminum stress in pots. J Korean Soc Grassl Forage Sci. 2021;41:162–167.
  • Rahman S U, Xuebin Q, Riaz L, et al. The interactive effect of pH variation and cadmium stress on wheat (Triticum aestivum L.) growth, physiological and biochemical parameters. PLoS One. 2021;16:e0253798.
  • Backer R, Rokem JS, Ilangumaran G, et al. Plant growth-promoting rhizobacteria: context, mechanisms of action, and roadmap to commercialization of biostimulants for sustainable agriculture. Front Plant Sci. 2018;9:1473.
  • Prado C, Chocobar Ponce S, Pagano E, et al. Differential physiological responses of two Salvinia species to hexavalent chromium at a glance. Aquat Toxicol. 2016;175:213–221.
  • Haider FU, Wang X, Farooq M, et al. Biochar application for the remediation of trace metals in contaminated soils: implications for stress tolerance and crop production. Ecotoxicol Environ Saf. 2022;230:113165.
  • Ibáñez SG, Alderete LGS, Medina MI, et al. Phytoremediation of phenol using Vicia sativa L. plants and its antioxidative response. Environ Sci Pollut Res. 2012;19:1555–1562.
  • Wang RG, Zhao X, Wang TC, et al. Can we use mine waste as substrate in constructed wetlands to intensify nutrient removal? A critical assessment of key removal mechanisms and long-term environmental risks. Water Res. 2022;210:118009.
  • Yan A, Wang Y, Tan SN, et al. Phytoremediation: a promising approach for revegetation of heavy metal-polluted land. Front Plant Sci. 2020;11:359.

Reprints and Corporate Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

To request a reprint or corporate permissions for this article, please click on the relevant link below:

Order Reprints Request Corporate Permissions

Academic Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

Obtain permissions instantly via Rightslink by clicking on the button below:

Request Academic Permissions

If you are unable to obtain permissions via Rightslink, please complete and submit this Permissions form. For more information, please visit our Permissions help page.

Related research

People also read lists articles that other readers of this article have read.

Recommended articles lists articles that we recommend and is powered by our AI driven recommendation engine.

Cited by lists all citing articles based on Crossref citations.
Articles with the Crossref icon will open in a new tab.