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ادغام زیستپالایی و فناوری پیل سوختی میکروبی: نقش میکروارگانیسمهای خاک در تجزیه آلایندهها و تولید زیستی الکتریسیته | ||
| تحقیقات آب و خاک ایران | ||
| دوره 57، شماره 1، فروردین 1405، صفحه 209-247 اصل مقاله (2.82 M) | ||
| نوع مقاله: مروری | ||
| شناسه دیجیتال (DOI): 10.22059/ijswr.2026.406137.670051 | ||
| نویسندگان | ||
| شایان شریعتی* 1؛ هادی مسیب زاده2؛ حمید مقیمی3 | ||
| 1گروه مهندسی محیط زیست، دانشکده محیط زیست، دانشگاه تهران، تهران، ایران. | ||
| 2گروه مهندسی محیط زیست، دانشکده محیط زیست، دانشگاه تهران، تهران، ایران | ||
| 3دانشیار گروه میکروبیولوژی، دانشکده زیست شناسی دانشگاه تهران، تهران، ایران | ||
| چکیده | ||
| با تشدید نگرانیهای جهانی پیرامون آلودگی آب و خاک و پیامدهای فزاینده تغییرات اقلیمی، نیاز به فناوریهای نوینی که بتوانند بهطور همزمان زیستپالایی آلایندهها و تولید انرژی پاک را محقق سازند، بیش از پیش احساس میشود. در این میان، پیلهای سوختی میکروبی (MFCs) و گونههای خاکی رسوبی آنها (SMFCs) بهعنوان سامانههای زیستالکتروشیمیایی نوظهور مطرح شدهاند که قادرند انرژی شیمیایی مواد آلی را از طریق فعالیت متابولیکی میکروارگانیسمهای الکتروژن، به جریان الکتریکی تبدیل کنند و همزمان در تجزیه و حذف آلایندههای مقاوم نقش داشته باشند. جوامع میکروبی مستقر در رسوبات و لایههای خاکی، بهویژه از طریق تشکیل زیستلایههای آندی و تسهیل انتقال مستقیم یا واسطهای الکترون، نقشی تعیینکننده در عملکرد و کارایی این سامانهها ایفا میکنند. با این حال، ماهیت باز و دینامیک محیطهای عملیاتی SMFCs منجر به توالی اکولوژیکی میکروبی میشود که میتواند پایداری الکتروشیمیایی و بازده بلندمدت سامانه را تحت تأثیر قرار دهد. علیرغم پیشرفتهای قابل توجه در این حوزه، محدودیت در تنوع گونههای الکتروژن کارآمد، رقابت میان میکروارگانیسمهای الکتروژن و غیرالکتروژن، و چالشهای مرتبط با پایداری زیستلایهها همچنان از موانع اصلی توسعه و بهکارگیری این فناوریها در مقیاس صنعتی به شمار میروند. این مقاله مروری با تمرکز بر جنبههای میکروبی و الکتروشیمیایی پیلهای سوختی میکروبی و انواع مبتنی بر خاک و رسوب آنها، به بررسی سازوکارهای انتقال الکترون، پویایی جوامع میکروبی در نواحی آندی و کاتدی، و تأثیر پارامترهای الکتروشیمیایی بر عملکرد سامانه میپردازد. افزون بر این، چشماندازهای آینده شامل توسعه کنسرسیومهای میکروبی مهندسیشده با عملکردهای مکمل، بهکارگیری راهبردهای تحریک زیستی برای تنظیم جانشینی میکروبی، و بهینهسازی شرایط عملیاتی بهمنظور افزایش همزمان بازده تولید برق و کارایی زیستپالایی مورد بحث قرار میگیرد. یافتههای این مرور میتواند زمینهساز طراحی سامانههایی پایدارتر و کارآمدتر برای مدیریت محیطزیست و تولید انرژیهای تجدیدپذیر باشد. | ||
| کلیدواژهها | ||
| آلودگی خاک و آب؛ آلایندههای آلی و معدنی؛ تولید انرژی سبز؛ سلول سوختی میکروبی؛ زیستپالایی | ||
| عنوان مقاله [English] | ||
| Integrating Bioremediation and Microbial Fuel Cell Technologies: The Role of Soil Microbial Communities In Contaminant Degradation and Bioelectricity Generation | ||
| نویسندگان [English] | ||
| Shayan Shariati1؛ Hadi Mosayebzade2؛ Hamid Moghimi3 | ||
| 1Department of Environmental Engineering, Faculty of Environment, University of Tehran, Tehran, Iran. | ||
| 2Department of Environmental Engineering, Faculty of Environment, University of Tehran, Tehran. | ||
| 3Department of Microbial Biotechnology, School of Biology, College of Science, University of Tehran, Tehran, Iran | ||
| چکیده [English] | ||
| With growing global concerns about soil and water pollution and the escalating impacts of climate change, there is an urgent need for innovative technologies capable of simultaneously achieving bioremediation and clean energy generation. Microbial fuel cells (MFCs) and their sediment- or soil-based variants (SMFCs) have emerged as promising bioelectrochemical systems that convert the chemical energy of organic matter into electrical energy through the metabolic activity of electrogenic microorganisms, while concurrently degrading resistant pollutants. Microbial communities residing in sediments and soil layers, particularly those forming anodic biofilms, play a crucial role in system performance by facilitating direct and mediated electron transfer. However, the open and dynamic nature of SMFC environments leads to complex microbial succession, influencing the electrochemical stability and long-term efficiency of the system. Despite significant progress, challenges such as limited diversity of efficient electroactive species, competition between non-electrogenic and electrogenic microorganisms, and biofilm instability continue to restrict large-scale deployment. This review focuses on the microbial and electrochemical aspects of MFCs and SMFCs, discussing electron transfer mechanisms, microbial community dynamics in anodic and cathodic zones, and the influence of electrochemical parameters on system performance. Future perspectives include the development of engineered microbial consortia with complementary functionalities, integration of biostimulation strategies to regulate microbial succession, and optimization of operational conditions to enhance both power generation and bioremediation efficiency. The insights presented in this review may facilitate the design of more sustainable and efficient systems for environmental management and renewable energy production. | ||
| کلیدواژهها [English] | ||
| Bioremediation, Green energy production, Microbial fuel cell (MFC), Organic and inorganic contaminants Soil and water pollution | ||
| مراجع | ||
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Abbas, S. Z., & Rafatullah, M. (2021). Recent advances in soil microbial fuel cells for soil contaminants remediation. Chemosphere, 272, 129691. Abbas, S. Z., Rafatullah, M., Khan, M. A., & Siddiqui, M. R. (2019). Bioremediation and electricity generation by using open and closed sediment microbial fuel cells. Frontiers in microbiology, 9, 3348. Abd-Elrahman, N. K., Al-Harbi, N., Basfer, N. M., Al-Hadeethi, Y., Umar, A., & Akbar, S. (2022). Applications of nanomaterials in microbial fuel cells: a review. Molecules, 27(21), 7483. Agrahari, R., Bayar, B., Abubackar, H. N., Giri, B. S., Rene, E. R., & Rani, R. (2022). Advances in the development of electrode materials for improving the reactor kinetics in microbial fuel cells. Chemosphere, 290, 133184. Aiyer, K. S. (2020). How does electron transfer occur in microbial fuel cells? World Journal of Microbiology and Biotechnology, 36(2), 19. Alikhani, H. A., Shariati, S., Etesami, H., & Fallah Nosrat Abad, A. (2022). Azotobacter as a Rice Plant (Oryza sativa L.) Growth Promoting Biofertilizer. Iranian Journal of Soil and Water Research, 53(3), 633–661. An, G., Yan, R., Fu, Z., Chen, Z., Guo, Y., Yang, J., & Zhou, Y. (2023). Adaptation of anammox consortia in microbial fuel cell to low temperature: microbial community and predictive functional profiling. Bioresource Technology, 370, 128565. Anderson‐Teixeira, K. J., Davis, S. C., Masters, M. D., & Delucia, E. H. (2009). Changes in soil organic carbon under biofuel crops. Gcb Bioenergy, 1(1), 75–96. Aparicio, J. D., Raimondo, E. E., Saez, J. M., Costa-Gutierrez, S. B., Alvarez, A., Benimeli, C. S., & Polti, M. A. (2022). The current approach to soil remediation: A review of physicochemical and biological technologies, and the potential of their strategic combination. Journal of Environmental Chemical Engineering, 10(2), 107141. Banerjee, A., Calay, R. K., & Mustafa, M. (2022). Review on material and design of anode for microbial fuel cell. Energies, 15(6), 2283. Baranitharan, E., Khan, M. R., Prasad, D., Teo, W. F. A., Tan, G. Y. A., & Jose, R. (2015). Effect of biofilm formation on the performance of microbial fuel cell for the treatment of palm oil mill effluent. Bioprocess and biosystems engineering, 38(1), 15–24. Borello, D., Gagliardi, G., Aimola, G., Ancona, V., Grenni, P., Bagnuolo, G., Garbini, G. L., Rolando, L., & Caracciolo, A. B. (2021). Use of microbial fuel cells for soil remediation: A preliminary study on DDE. International journal of hydrogen energy, 46(16), 10131–10142. Cai, X., Yuan, Y., Yu, L., Zhang, B., Li, J., Liu, T., Yu, Z., & Zhou, S. (2020). Biochar enhances bioelectrochemical remediation of pentachlorophenol-contaminated soils via long-distance electron transfer. Journal of hazardous materials, 391, 122213. Cao, M., Yin, J., Song, T., & Xie, J. (2022). Effects of the presence of phosphate buffer solution on removal efficiency of Pb and Zn in soil by solid phase microbial fuel cells. Biotechnology Letters, 44(12), 1495–1505. Cao, X., Song, H.-l., Yu, C.-y., & Li, X.-n. (2015). Simultaneous degradation of toxic refractory organic pesticide and bioelectricity generation using a soil microbial fuel cell. Bioresource Technology, 189, 87–93. Casula, E., Kim, B., Chesson, H., Di Lorenzo, M., & Mascia, M. (2021). Modelling the influence of soil properties on performance and bioremediation ability of a pile of soil microbial fuel cells. Electrochimica acta, 368, 137568. Chakraborty, I., Sathe, S., Khuman, C., & Ghangrekar, M. (2020). Bioelectrochemically powered remediation of xenobiotic compounds and heavy metal toxicity using microbial fuel cell and microbial electrolysis cell. Materials Science for Energy Technologies, 3, 104–115. Chandrasekhar, K., & Mohan, S. V. (2014a). Bio-electrohydrolysis as a pretreatment strategy to catabolize complex food waste in closed circuitry: function of electron flux to enhance acidogenic biohydrogen production. International journal of hydrogen energy, 39(22), 11411–11422. Chandrasekhar, K., & Mohan, S. V. (2014b). Induced catabolic bio-electrohydrolysis of complex food waste by regulating external resistance for enhancing acidogenic biohydrogen production. Bioresource Technology, 165, 372–382. Chen, Z., Zhu, B.-K., Jia, W.-F., Liang, J.-H., & Sun, G.-X. (2015). Can electrokinetic removal of metals from contaminated paddy soils be powered by microbial fuel cells? Environmental Technology & Innovation, 3, 63–67. Cheng, S., & Logan, B. E. (2007). Ammonia treatment of carbon cloth anodes to enhance power generation of microbial fuel cells. Electrochemistry Communications, 9(3), 492–496. Choi, S. (2022). Electrogenic bacteria promise new opportunities for powering, sensing, and synthesizing. Small, 18(18), 2107902. Choudhury, P., Prasad Uday, U. S., Bandyopadhyay, T. K., Ray, R. N., & Bhunia, B. (2017). Performance improvement of microbial fuel cell (MFC) using suitable electrode and Bioengineered organisms: A review. Bioengineered, 8(5), 471–487. Conners, E. M., Rengasamy, K., & Bose, A. (2022). Electroactive biofilms: how microbial electron transfer enables bioelectrochemical applications. Journal of Industrial Microbiology and Biotechnology, 49(4), kuac012. Cui, H., Wang, J., Feng, K., & Xing, D. (2022). Digestate of fecal sludge enhances the tetracycline removal in soil microbial fuel cells. Water, 14(17), 2752. De Celis, M., Serrano-Aguirre, L., Belda, I., Liébana-García, R., Arroyo, M., Marquina, D., de la Mata, I., & Santos, A. (2021). Acylase enzymes disrupting quorum sensing alter the transcriptome and phenotype of Pseudomonas aeruginosa, and the composition of bacterial biofilms from wastewater treatment plants. Science of The Total Environment, 799, 149401. De Schamphelaire, L., Rabaey, K., Boeckx, P., Boon, N., & Verstraete, W. (2008). Outlook for benefits of sediment microbial fuel cells with two bio‐electrodes. Microbial biotechnology, 1(6), 446–462. Deng, Z., Zhu, J., Yang, L., Zhang, Z., Li, B., Xia, L., & Wu, L. (2022). Microalgae fuel cells enhanced biodegradation of imidacloprid by Chlorella sp. Biochemical Engineering Journal, 179, 108327. Dharmalingam, S., Kugarajah, V., & Sugumar, M. (2019). Membranes for microbial fuel cells. In Microbial electrochemical technology (pp. 143–194). Elsevier. Din, M. I., Ahmed, M., Ahmad, M., Iqbal, M., Ahmad, Z., Hussain, Z., Khalid, R., & Samad, A. (2023). Investigating the Activity of Carbon Fiber Electrode for Electricity Generation from Waste Potatoes in a Single‐Chambered Microbial Fuel Cell. Journal of Chemistry, 2023(1), 8520657. Dolfing, J. (2014). Syntrophy in microbial fuel cells. The ISME journal, 8(1), 4–5. Domínguez-Garay, A., Boltes, K., & Esteve-Núñez, A. (2016). Cleaning-up atrazine-polluted soil by using microbial electroremediating cells. Chemosphere, 161, 365–371. Du, C., & Liu, W. (2024). Defending against environmental threats: unveiling household adaptation strategies and population heterogeneity. Environment International, 190, 108858. Dwivedi, K. A., Huang, S.-J., Wang, C.-T., & Kumar, S. (2022). Fundamental understanding of microbial fuel cell technology: Recent development and challenges. Chemosphere, 288, 132446. Dziegielowski, J., Mascia, M., Metcalfe, B., & Di Lorenzo, M. (2023). Voltage evolution and electrochemical behaviour of Soil microbial fuel cells operated in different quality soils. Sustainable Energy Technologies and Assessments, 56, 103071. Feng, W., Wu, X., Mao, G., Zhao, T., Wang, W., Chen, Y., Zhang, M., Yang, L., & Wu, X. (2020). Neurological effects of subchronic exposure to dioctyl phthalate (DOP), lead, and arsenic, individual and mixtures, in immature mice. Environmental Science and Pollution Research, 27(9), 9247–9260. Firdous, S., Jin, W., Shahid, N., Bhatti, Z., Iqbal, A., Abbasi, U., Mahmood, Q., & Ali, A. (2018). The performance of microbial fuel cells treating vegetable oil industrial wastewater. Environmental Technology & Innovation, 10, 143–151. Foladori, P., Vaccari, M., & Vitali, F. (2015). Energy audit in small wastewater treatment plants: methodology, energy consumption indicators, and lessons learned. Water Science and Technology, 72(6), 1007–1015. Galloway, J. N., Dentener, F. J., Capone, D. G., Boyer, E. W., Howarth, R. W., Seitzinger, S. P., Asner, G. P., Cleveland, C., Green, P., & Holland, E. (2004). Nitrogen cycles: past, present, and future. Biogeochemistry, 70(2), 153–226. Garbini, G. L., Barra Caracciolo, A., & Grenni, P. (2023). Electroactive bacteria in natural ecosystems and their applications in microbial fuel cells for bioremediation: A review. Microorganisms, 11(5), 1255. Garimella, S. S. S., Rachakonda, S. V., Pratapa, S. S., Mannem, G. D., & Mahidhara, G. (2024). From cells to power cells: harnessing bacterial electron transport for microbial fuel cells (MFCs). Annals of microbiology, 74(1), 19. Gautam, R., Nayak, J. K., Talapatra, K. N., & Ghosh, U. K. (2023). Assessment of different organic substrates for bio-electricity and bio-hydrogen generation in an integrated bio-electrochemical system. Materials Today: Proceedings, 80, 2255–2259. Ghorbannezhad, H., Moghimi, H., & Dastgheib, S. M. M. (2018). Evaluation of heavy petroleum degradation using bacterial-fungal mixed cultures. Ecotoxicology and Environmental Safety, 164, 434–439. Guadarrama‐Pérez, O., Gutiérrez‐Macías, T., García‐Sánchez, L., Guadarrama‐Pérez, V. H., & Estrada‐Arriaga, E. B. (2019). Recent advances in constructed wetland‐microbial fuel cells for simultaneous bioelectricity production and wastewater treatment: a review. International journal of energy research, 43(10), 5106–5127. Guan, C.-Y., Tseng, Y.-H., Tsang, D. C., Hu, A., & Yu, C.-P. (2019). Wetland plant microbial fuel cells for remediation of hexavalent chromium contaminated soils and electricity production. Journal of hazardous materials, 365, 137–145. Guo, L. B., & Gifford, R. M. (2002). Soil carbon stocks and land use change: a meta analysis. Global change biology, 8(4), 345–360. Guo, W., Cui, Y., Song, H., & Sun, J. (2014). Layer-by-layer construction of graphene-based microbial fuel cell for improved power generation and methyl orange removal. Bioprocess and biosystems engineering, 37(9), 1749–1758. Gustave, W., Yuan, Z.-F., Li, X., Ren, Y.-X., Feng, W.-J., Shen, H., & Chen, Z. (2020). Mitigation effects of the microbial fuel cells on heavy metal accumulation in rice (Oryza sativa L.). Environmental Pollution, 260, 113989. Gustave, W., Yuan, Z.-F., Sekar, R., Ren, Y.-X., Liu, J.-Y., Zhang, J., & Chen, Z. (2019). Soil organic matter amount determines the behavior of iron and arsenic in paddy soil with microbial fuel cells. Chemosphere, 237, 124459. Guzman, J. J., Kara, M. O. P., Frey, M. W., & Angenent, L. T. (2017). Performance of electro-spun carbon nanofiber electrodes with conductive poly (3, 4-ethylenedioxythiophene) coatings in bioelectrochemical systems. Journal of Power Sources, 356, 331–337. Hamed, M. S., Majdi, H. S., & Hasan, B. O. (2021). The effect of temperature on electrical energy production in double chamber microbial fuel cell using different electrode materials. Materials Today: Proceedings, 42, 3018–3021. Hiegemann, H., Littfinski, T., Krimmler, S., Lübken, M., Klein, D., Schmelz, K.-G., Ooms, K., Pant, D., & Wichern, M. (2019). Performance and inorganic fouling of a submergible 255 L prototype microbial fuel cell module during continuous long-term operation with real municipal wastewater under practical conditions. Bioresource Technology, 294, 122227. Hindatu, Y., Annuar, M., Subramaniam, R., & Gumel, A. (2017). Medium-chain-length poly-3-hydroxyalkanoates-carbon nanotubes composite anode enhances the performance of microbial fuel cell. Bioprocess and biosystems engineering, 40(6), 919–928. Holmes, D., Bond, D., O’neil, R., Reimers, C., Tender, L., & Lovley, D. (2004). Microbial communities associated with electrodes harvesting electricity from a variety of aquatic sediments. Microbial ecology, 48(2), 178–190. Hou, J., Liu, Z., Yang, S., & Zhou, Y. (2014). Three-dimensional macroporous anodes based on stainless steel fiber felt for high-performance microbial fuel cells. Journal of Power Sources, 258, 204–209. Huang, D.-Y., Zhou, S.-G., Chen, Q., Zhao, B., Yuan, Y., & Zhuang, L. (2011). Enhanced anaerobic degradation of organic pollutants in a soil microbial fuel cell. Chemical Engineering Journal, 172(2-3), 647–653. Ivars-Barceló, F., Zuliani, A., Fallah, M., Mashkour, M., Rahimnejad, M., & Luque, R. (2018). Novel applications of microbial fuel cells in sensors and biosensors. Applied Sciences, 8(7), 1184. Jiang, J., Wang, H., Zhang, S., Li, S., Zeng, W., & Li, F. (2021). The influence of external resistance on the performance of microbial fuel cell and the removal of sulfamethoxazole wastewater. Bioresource Technology, 336, 125308. Joutey, N. T., Bahafid, W., Sayel, H., & El Ghachtouli, N. (2013). Biodegradation: involved microorganisms and genetically engineered microorganisms. Biodegradation-life of science, 1, 289–320. Kabutey, F. T., Ding, J., Zhao, Q., Antwi, P., Quashie, F. K., Tankapa, V., & Zhang, W. (2019). Pollutant removal and bioelectricity generation from urban river sediment using a macrophyte cathode sediment microbial fuel cell (mSMFC). Bioelectrochemistry, 128, 241–251. Khan, N., Khan, M. D., Ansari, M. Y., Ahmad, A., & Khan, M. Z. (2019). Bio-electrodegradation of 2, 4, 6-Trichlorophenol by mixed microbial culture in dual chambered microbial fuel cells. Journal of bioscience and bioengineering, 127(3), 353–359. Kim, B., Dziegielowski, J., & Lorenzo, M. D. (2022). Soil Microbial Fuel Cells for Energy Harvesting and Bioremediation of Soil Contaminated with Organic Pollutants. Good Microbes in Medicine, Food Production, Biotechnology, Bioremediation, and Agriculture, 385–395. Kinyua, A., Mbugua, J., Mbui, D., Kithure, J., Wandiga, S., & Waswa, A. (2022). Microbial fuel cell bio-remediation of lambda cyhalothrin, malathion and chlorpyrifos on loam soil inoculated with bio-slurry. J Bioremediat Biodegrad, 13(508), 2. Kordek-Khalil, K., Altiok, E., Salvian, A., Siekierka, A., Torres-Mendieta, R., Avignone-Rossa, C., Pietrelli, A., Gadkari, S., Ieropoulos, I. A., & Yalcinkaya, F. (2023). Nanocomposite use in MFCs: a state of the art review. Sustainable Energy & Fuels, 7(24), 5608–5624. Kuo, J., Liu, D., Wang, S.-H., & Lin, C.-H. (2021). Dynamic changes in soil microbial communities with glucose enrichment in sediment microbial fuel cells. Indian Journal of Microbiology, 61(4), 497–505. Lal, R., Monger, C., Nave, L., & Smith, P. (2021). The role of soil in regulation of climate. Philosophical Transactions of the Royal Society B, 376(1834), 20210084. Leifeld, J. (2023). Carbon farming: Climate change mitigation via non-permanent carbon sinks. Journal of Environmental management, 339, 117893. Li, C., Mei, T., Song, T.-s., & Xie, J. (2022). Removal of petroleum hydrocarbon-contaminated soil using a solid-phase microbial fuel cell with a 3D corn stem carbon electrode modified with carbon nanotubes. Bioprocess and biosystems engineering, 45(7), 1137–1147. Li, M., Zhou, M., Tian, X., Tan, C., McDaniel, C. T., Hassett, D. J., & Gu, T. (2018). Microbial fuel cell (MFC) power performance improvement through enhanced microbial electrogenicity. Biotechnology advances, 36(4), 1316–1327. Li, W.-W., & Yu, H.-Q. (2015). Stimulating sediment bioremediation with benthic microbial fuel cells. Biotechnology advances, 33(1), 1–12. Li, X., Li, Y., Zhang, X., Zhao, X., Chen, X., & Li, Y. (2020). The metolachlor degradation kinetics and bacterial community evolution in the soil bioelectrochemical remediation. Chemosphere, 248, 125915. Li, X., Li, Y., Zhang, X., Zhao, X., Sun, Y., Weng, L., & Li, Y. (2019). Long-term effect of biochar amendment on the biodegradation of petroleum hydrocarbons in soil microbial fuel cells. Science of The Total Environment, 651, 796–806. Liang, Y., Ji, M., Zhai, H., & Zhao, J. (2021). Organic matter composition, BaP biodegradation and microbial communities at sites near and far from the bioanode in a soil microbial fuel cell. Science of The Total Environment, 772, 144919. Liao, Z.-H., Sun, J.-Z., Sun, D.-Z., Si, R.-W., & Yong, Y.-C. (2015). Enhancement of power production with tartaric acid doped polyaniline nanowire network modified anode in microbial fuel cells. Bioresource Technology, 192, 831–834. Liu, C. H., Lee, S. K., Ou, I. C., Tsai, K. J., Lee, Y., Chu, Y. H., Liao, Y. T., & Liu, C. T. (2021). Essential factors that affect bioelectricity generation by Rhodopseudomonas palustris strain PS3 in paddy soil microbial fuel cells. International journal of energy research, 45(2), 2231–2244. Liu, H., & Logan, B. E. (2004). Electricity generation using an air-cathode single chamber microbial fuel cell in the presence and absence of a proton exchange membrane. Environmental science & technology, 38(14), 4040–4046. Louwagie, G., Gay, S. H., Sammeth, F., & Ratinger, T. (2011). The potential of European Union policies to address soil degradation in agriculture. Land degradation & development, 22(1), 5–17. Lovley, D. R., Giovannoni, S. J., White, D. C., Champine, J. E., Phillips, E., Gorby, Y. A., & Goodwin, S. (1993). Geobacter metallireducens gen. nov. sp. nov., a microorganism capable of coupling the complete oxidation of organic compounds to the reduction of iron and other metals. Archives of microbiology, 159(4), 336–344. Lu, L., Huang, Z., Rau, G. H., & Ren, Z. J. (2015). Microbial electrolytic carbon capture for carbon negative and energy positive wastewater treatment. Environmental science & technology, 49(13), 8193–8201. Luckarift, H. R., Sizemore, S. R., Farrington, K. E., Roy, J., Lau, C., Atanassov, P. B., & Johnson, G. R. (2012). Facile fabrication of scalable, hierarchically structured polymer/carbon architectures for bioelectrodes. ACS applied materials & interfaces, 4(4), 2082–2087. Ma, J., Wang, A., & Weng, Z. (2024). Do policies make a difference? Assessing the impact of China's air pollution prevention and control action plan on carbon emissions. Journal of Environmental management, 370, 122685. Ma, J., Zhang, Q., Chen, F., Lu, S., Wang, Y., & Liang, H. (2021). Simultaneous removal of copper and biodegradation of BDE-209 with soil microbial fuel cells. Journal of Environmental Chemical Engineering, 9(4), 105593. Mandal, A., Majumder, A., Dhaliwal, S., Toor, A., Mani, P. K., Naresh, R., Gupta, R. K., & Mitran, T. (2022). Impact of agricultural management practices on soil carbon sequestration and its monitoring through simulation models and remote sensing techniques: A review. Critical Reviews in Environmental Science and Technology, 52(1), 1–49. Mandanipour, V. (2021). Chemical Modification of Proton Exchanger Sulfonated Polystyrene with Sulfonated Graphene Oxide for Application as a New Polymer Electrolyte Membrane in Direct Methanol Fuel Cell. Iran. J. Chem. Chem. Eng. (Iranian Journal of Chemistry and Chemical Engineering), 40(6), 1973–1984. Martins, G., Peixoto, L., Teodorescu, S., Parpot, P., Nogueira, R., & Brito, A. (2014). Impact of an external electron acceptor on phosphorus mobility between water and sediments. Bioresource Technology, 151, 419–423. Megharaj, M., Ramakrishnan, B., Venkateswarlu, K., Sethunathan, N., & Naidu, R. (2011). Bioremediation approaches for organic pollutants: a critical perspective. Environment International, 37(8), 1362–1375. Methe, B., Nelson, K. E., Eisen, J., Paulsen, I., Nelson, W., Heidelberg, J., Wu, D., Wu, M., Ward, N., & Beanan, M. (2003). Genome of Geobacter sulfurreducens: metal reduction in subsurface environments. Science, 302(5652), 1967–1969. Moghimi, H., HEIDARY, T. R., & Hamedi, J. (2016). Evaluation of crude oil biodegradation by Phaeosphaeria spp. UTMC 5003. Moghimi, H., Shafiee, Z., Reshadi, M. A. M., & Bazargan, A. (2025). Remediation of pseudomonas aeruginosa and landfill leachate biofilms with electromagnetic fields. Clean Technologies and Environmental Policy, 1–16. Mohanakrishna, G., Al-Raoush, R. I., Abu-Reesh, I. M., & Pant, D. (2019). A microbial fuel cell configured for the remediation of recalcitrant pollutants in soil environment. RSC advances, 9(71), 41409–41418. Nandy, A., Kim, B., & Di Lorenzo, M. (2022). Minimalistic soil microbial fuel cells for bioremediation of recalcitrant pollutants. E3S Web of Conferences, Nascimento, C. M., de Sousa Mendes, W., Silvero, N. E. Q., Poppiel, R. R., Sayão, V. M., Dotto, A. C., Dos Santos, N. V., Amorim, M. T. A., & Demattê, J. A. (2021). Soil degradation index developed by multitemporal remote sensing images, climate variables, terrain and soil atributes. Journal of Environmental management, 277, 111316. Nawaz, A., Raza, W., Gul, H., Durrani, A. K., Algethami, F. K., Sonne, C., & Kim, K.-H. (2020). Upscaling feasibility of a graphite-based truncated conical microbial fuel cell for bioelectrogenesis through organic wastewater treatment. Journal of colloid and interface science, 570, 99–108. Noori, M. T., Ghangrekar, M., Mukherjee, C., & Min, B. (2019). Biofouling effects on the performance of microbial fuel cells and recent advances in biotechnological and chemical strategies for mitigation. Biotechnology advances, 37(8), 107420. Olabi, A. G., Wilberforce, T., & Abdelkareem, M. A. (2021). Fuel cell application in the automotive industry and future perspective. Energy, 214, 118955. Ortega-Martínez, A., Juárez-López, K., Solorza-Feria, O., Ponce-Noyola, M., Galindez-Mayer, J., Rinderknecht-Seijas, N., & Poggi-Varaldo, H. (2013). Analysis of microbial diversity of inocula used in a five-face parallelepiped and standard microbial fuel cells. International journal of hydrogen energy, 38(28), 12589–12599. Pal, M., Shrivastava, A., & Sharma, R. K. (2023). Performance of microbial fuel cell using nanomaterials for electrode modification. EMERGING TECHNOLOGIES; MICRO TO NANO: Proceedings of ETMN-2021, 2752(1), 060005. Panepinto, D., Fiore, S., Zappone, M., Genon, G., & Meucci, L. (2016). Evaluation of the energy efficiency of a large wastewater treatment plant in Italy. Applied Energy, 161, 404–411. Park, D. H., & Zeikus, J. G. (2000). Electricity generation in microbial fuel cells using neutral red as an electronophore. Applied and environmental microbiology, 66(4), 1292–1297. Pasternak, G., Greenman, J., & Ieropoulos, I. (2019). Removal of Hepatitis B virus surface HBsAg and core HBcAg antigens using microbial fuel cells producing electricity from human urine. Scientific reports, 9(1), 11787. Pednekar, R. R., & Rajan, A. P. (2024). Unraveling the contemporary use of microbial fuel cell in pesticide degradation and simultaneous electricity generation: a review. Environmental Science and Pollution Research, 31(1), 144–166. Pei, Y., Yang, Y., Chen, L., Yang, Y., & Song, L. (2023). Remediation of chromium-contaminated soil in semi-arid areas by combined chemical reduction and stabilization. Environmental Pollutants and Bioavailability, 35(1), 2157332. Pu, K.-B., Ma, Q., Cai, W.-F., Chen, Q.-Y., Wang, Y.-H., & Li, F.-J. (2018). Polypyrrole modified stainless steel as high performance anode of microbial fuel cell. Biochemical Engineering Journal, 132, 255–261. Qin, B., Luo, H., Liu, G., Zhang, R., Chen, S., Hou, Y., & Luo, Y. (2012). Nickel ion removal from wastewater using the microbial electrolysis cell. Bioresource Technology, 121, 458–461. Qiu, Y., Yu, Y., Li, H., Yan, Z., Li, Z., Liu, G., Zhang, Z., & Feng, Y. (2020). Enhancing carbon and nitrogen removals by a novel tubular bio-electrochemical system with functional biocathode coupling with oxygen-producing submerged plants. Chemical Engineering Journal, 402, 125400. Rafieenia, R., Mahmoud, M., El-Gohary, F., & Rossa, C. A. (2022). Microbial electrochemical systems for enhanced degradation of glyphosate: Electrochemical performance, degradation efficiency, and analysis of the anodic microbial community. bioRxiv, 2022.2002. 2021.481054. Rahimnejad, M., Adhami, A., Darvari, S., Zirepour, A., & Oh, S.-E. (2015). Microbial fuel cell as new technology for bioelectricity generation: A review. Alexandria Engineering Journal, 54(3), 745–756. Reimers, C. E., Tender, L. M., Fertig, S., & Wang, W. (2001). Harvesting energy from the marine sediment− water interface. Environmental science & technology, 35(1), 192–195. Ren, Y., Chen, J., Li, X., Yang, N., & Wang, X. (2018). Enhanced bioelectricity generation of air-cathode buffer-free microbial fuel cells through short-term anolyte pH adjustment. Bioelectrochemistry, 120, 145–149. Rossi, R., Jones, D., Myung, J., Zikmund, E., Yang, W., Gallego, Y. A., Pant, D., Evans, P. J., Page, M. A., & Cropek, D. M. (2019). Evaluating a multi-panel air cathode through electrochemical and biotic tests. Water research, 148, 51–59. Rossmann, F., Brenzinger, S., Knauer, C., Dörrich, A. K., Bubendorfer, S., Ruppert, U., Bange, G., & Thormann, K. M. (2015). The role of FlhF and HubP as polar landmark proteins in S hewanella putrefaciens CN‐32. Molecular microbiology, 98(4), 727–742. Rozendal, R. A., Hamelers, H. V., & Buisman, C. J. (2006). Effects of membrane cation transport on pH and microbial fuel cell performance. Environmental science & technology, 40(17), 5206–5211. Salman, M. Y., & Hasar, H. (2023). Review on environmental aspects in smart city concept: Water, waste, air pollution and transportation smart applications using IoT techniques. Sustainable Cities and Society, 94, 104567. Sarker, S., Akbor, M. A., Nahar, A., Hasan, M., Islam, A. R. M. T., & Siddique, M. A. B. (2021). Level of pesticides contamination in the major river systems: A review on South Asian countries perspective. Heliyon, 7(6). Sarmin, S., Tarek, M., Cheng, C. K., Roopan, S. M., & Khan, M. M. R. (2021). Augmentation of microbial fuel cell and photocatalytic polishing technique for the treatment of hazardous dimethyl phthalate containing wastewater. Journal of hazardous materials, 415, 125587. Sathe, S., Chakraborty, I., Cheela, V. S., Chowdhury, S., Dubey, B., & Ghangrekar, M. (2021). A novel bio-electro-Fenton process for eliminating sodium dodecyl sulphate from wastewater using dual chamber microbial fuel cell. Bioresource Technology, 341, 125850. Semenec, L., Laloo, A. E., Schulz, B. L., Vergara, I. A., Bond, P. L., & Franks, A. E. (2018). Deciphering the electric code of Geobacter sulfurreducens in cocultures with Pseudomonas aeruginosa via SWATH-MS proteomics. Bioelectrochemistry, 119, 150–160. Shariati, S., Mehrdadi, N., Alikhani, H. A., & Zeynali, K. (2025). The role of cadmium-resistant bacteria and modifiers in improving rice crop quality. Iranian Journal of Soil and Water Research. Shariati, S., Pourbabaee, A. A., Alikhani, H. A., & Rezaei, K. (2022). Degradation of phthalic acid esters by the microbial consortium isolated from a contaminated soil. Applied Soil Research, 10(2), 1–13. Shariati, S., Pourbabaee, A. A., Alikhani, H. A., & Rezaei, K. A. (2021). Biodegradation of DEHP by a new native consortium An6 (Gordonia sp. and Pseudomonas sp.) adapted with phthalates, isolated from a natural strongly polluted wetland. Environmental Technology & Innovation, 24, 101936. Shariati, S., Pourbabaei, A. A., Alikhani, H. A., Rezaei, K. A., & Shariati, F. (2021). Phthalic acid esters as pervasive emerging pollutants in the environment and their role in threatening food security and human health: A review. Iranian Journal of Soil and Water Research, 52(8), 2253–2277. Siksnelyte-Butkiene, I., Zavadskas, E. K., & Streimikiene, D. (2020). Multi-criteria decision-making (MCDM) for the assessment of renewable energy technologies in a household: A review. Energies, 13(5), 1164. Simeon, I. M., Weig, A., & Freitag, R. (2022). Optimization of soil microbial fuel cell for sustainable bio-electricity production: combined effects of electrode material, electrode spacing, and substrate feeding frequency on power generation and microbial community diversity. Biotechnology for biofuels and bioproducts, 15(1), 124. Singh, S. (2001). Exploring correlation between redox potential and other edaphic factors in field and laboratory conditions in relation to methane efflux. Environment International, 27(4), 265–274. Sirajudeen, A. A. O., Annuar, M. S. M., Ishak, K. A., Yusuf, H., & Subramaniam, R. (2021). Innovative application of biopolymer composite as proton exchange membrane in microbial fuel cell utilizing real wastewater for electricity generation. Journal of Cleaner Production, 278, 123449. Sonawane, J. M., & Greener, J. (2024). Multiparameter optimization of microbial fuel cell outputs using linear sweep voltammetry and microfluidics. Journal of Power Sources, 607, 234589. Song, N., Jiang, H., & Yan, Z. (2019). Contrasting effects of sediment microbial fuel cells (SMFCs) on the degradation of macrophyte litter in sediments from different areas of a shallow eutrophic lake. Applied Sciences, 9(18), 3703. Song, W., & Liu, M. (2017). Farmland conversion decreases regional and national land quality in China. Land degradation & development, 28(2), 459–471. Sreelekshmy, B. (2020). Exploration of Electrochemcially Active Bacterial Strains for Microbial Fuel Cells: An Innovation in Bioelectricity Generation. Journal of Pure & Applied Microbiology, 14(1). Sun, F., Yang, Y., Zhang, Z., He, W., Chen, J., & Tang, M. (2025). Synergistic uranium (VI) remediation and bioenergy recovery via polyaniline-derived covalent organic framework-carbon nanotube (PANI@ COF-CNT) integrated sludge microbial fuel cell (SMFC): Mechanisms and microbial adaptation. Journal of Environmental Chemical Engineering, 118598. Sur, S., & Sathiavelu, M. (2022). A concise overview on pesticide detection and degradation strategies. Environmental Pollutants and Bioavailability, 34(1), 112–126. Suransh, J., & Mungray, A. K. (2022). Reduction in particle size of vermiculite and production of the low-cost earthen membrane to achieve enhancement in the microbial fuel cell performance. Journal of Environmental Chemical Engineering, 10(6), 108787. Syed, Z., Sonu, K., & Sogani, M. (2022). Cattle manure management using microbial fuel cells for green energy generation. Biofuels, Bioproducts and Biorefining, 16(2), 460–470. Tang, K., He, C., Ma, C., & Wang, D. (2019). Does carbon farming provide a cost‐effective option to mitigate GHG emissions? Evidence from China. Australian Journal of Agricultural and Resource Economics, 63(3), 575–592. Touch, N., Hibino, T., Kinjo, N., & Morimoto, Y. (2018). Exploratory study on improving the benthic environment in sediment by sediment microbial fuel cells. International Journal of Environmental Science and Technology, 15(3), 507–512. Trivedi, P., Schenk, P. M., Wallenstein, M. D., & Singh, B. K. (2017). Tiny microbes, big yields: enhancing food crop production with biological solutions. Microbial biotechnology, 10(5), 999–1003. Umar, M. F., Abbas, S. Z., Mohamad Ibrahim, M. N., Ismail, N., & Rafatullah, M. (2020). Insights into advancements and electrons transfer mechanisms of electrogens in benthic microbial fuel cells. Membranes, 10(9), 205. Valimandanipour, V., Noroozifar, M. (2017). Preparation and characterization of sulfonated polystyrene–polyethylene composite membrane for direct methanol fuel cell. Iran. J. Chem. Chem. Eng. (Iranian Journal of Chemistry and Chemical Engineering), 5, 151–162. Varma, M., Gupta, A. K., Ghosal, P. S., & Majumder, A. (2021). A review on performance of constructed wetlands in tropical and cold climate: Insights of mechanism, role of influencing factors, and system modification in low temperature. Science of The Total Environment, 755, 142540. Vélez-Pérez, L., Ramirez-Nava, J., Hernández-Flores, G., Talavera-Mendoza, O., Escamilla-Alvarado, C., Poggi-Varaldo, H., Solorza-Feria, O., & López-Díaz, J. (2020). Industrial acid mine drainage and municipal wastewater co-treatment by dual-chamber microbial fuel cells. International journal of hydrogen energy, 45(26), 13757–13766. Verma, P., Daverey, A., Kumar, A., & Arunachalam, K. (2021). Microbial fuel cell–a sustainable approach for simultaneous wastewater treatment and energy recovery. Journal of Water Process Engineering, 40, 101768. Vishwanathan, A. (2021). Microbial fuel cells: a comprehensive review for beginners. 3 Biotech, 11(5), 248. Waldrop, M., Harden, J. W., Turetsky, M., Petersen, D. G., McGuire, A., Briones, M., Churchill, A., Doctor, D., & Pruett, L. (2012). Bacterial and enchytraeid abundance accelerate soil carbon turnover along a lowland vegetation gradient in interior Alaska. Soil Biology and Biochemistry, 50, 188–198. Wang, H., Li, L., Cao, X., Long, X., & Li, X. (2017). Enhanced degradation of atrazine by soil microbial fuel cells and analysis of bacterial community structure. Water, Air, & Soil Pollution, 228(8), 308. Wang, H., Shen, X., Zhang, C., Shao, Y., Li, H., Wu, J., Yang, Y., & Song, H. (2024). Effects of plasticizer on removal of antibiotics and antibiotic resistance genes from agricultural soils via soil microbial fuel cells. Pedosphere, 34(6), 981–992. Wang, H., Song, H., Yu, R., Cao, X., Fang, Z., & Li, X. (2016). New process for copper migration by bioelectricity generation in soil microbial fuel cells. Environmental Science and Pollution Research, 23(13), 13147–13154. Wang, H., Zhang, H., Zhang, X., Li, Q., Cheng, C., Shen, H., & Zhang, Z. (2020). Bioelectrochemical remediation of Cr (VI)/Cd (II)-contaminated soil in bipolar membrane microbial fuel cells. Environmental research, 186, 109582. Wang, Y., Hu, J., Wang, L., Shan, D., Wang, X., Zhang, Y., Mao, X., Xing, L., & Wang, D. (2016). Acclimated sediment microbial fuel cells from a eutrophic lake for the in situ denitrification process. RSC advances, 6(83), 80079–80085. Wang, Y., Zhang, X., & Lin, H. (2024). Effects of pH on simultaneous Cr (VI) and p-chlorophenol removal and electrochemical performance in Leersia hexandra constructed wetland-microbial fuel cell. Environmental technology, 45(3), 483–494. Wanwimolruk, S., Phopin, K., Boonpangrak, S., & Prachayasittikul, V. (2016). Food safety in Thailand 4: Comparison of pesticide residues found in three commonly consumed vegetables purchased from local markets and supermarkets in Thailand. PeerJ, 4, e2432. Wong, P. Y., Cheng, K. Y., Krishna, K. B., Kaksonen, A. H., Sutton, D. C., & Ginige, M. P. (2018). Improvement of carbon usage for phosphorus recovery in EBPR-r and the shift in microbial community. Journal of Environmental management, 218, 569–578. Wu, M., Xu, X., Lu, K., & Li, X. (2019). Effects of the presence of nanoscale zero-valent iron on the degradation of polychlorinated biphenyls and total organic carbon by sediment microbial fuel cell. Science of The Total Environment, 656, 39–44. Wu, Q., Jiao, S., Ma, M., & Peng, S. (2020). Microbial fuel cell system: a promising technology for pollutant removal and environmental remediation. Environmental Science and Pollution Research, 27(7), 6749–6764. Xu, P., Xiao, E.-R., Xu, D., Zhou, Y., He, F., Liu, B.-Y., Zeng, L., & Wu, Z.-B. (2017). Internal nitrogen removal from sediments by the hybrid system of microbial fuel cells and submerged aquatic plants. PloS one, 12(2), e0172757. Xu, P., Xiao, E., Xu, D., Li, J., Zhang, Y., Dai, Z., Zhou, Q., & Wu, Z. (2018). Enhanced phosphorus reduction in simulated eutrophic water: a comparative study of submerged macrophytes, sediment microbial fuel cells, and their combination. Environmental technology, 39(9), 1144–1157. Yadav, D., Singh, S., & Sinha, R. (2021). Microbial degradation of organic contaminants in water bodies: technological advancements. Pollutants and Water Management: Resources, Strategies and Scarcity, 172–209. Yang, X., & Chen, S. (2021). Microorganisms in sediment microbial fuel cells: Ecological niche, microbial response, and environmental function. Science of The Total Environment, 756, 144145. Yang, X., Zhang, Z., & Zhang, J. (2023). Study of soil microplastic pollution and influencing factors based on environmental fragility theory. Science of The Total Environment, 899, 165435. Yang, Y., Chen, H., Majidzadeh, H., & Chow, A. T. (2018). Electricity generation from different wetlands: Mechanisms based on dissolved organic matters in membrane-less microbial fuel cells. Chemical Engineering Journal, 351, 1006–1012. Yaqoob, A. A., Al-Zaqri, N., Alamzeb, M., Hussain, F., Oh, S.-E., & Umar, K. (2023). Bioenergy generation and phenol degradation through microbial fuel cells energized by domestic organic waste. Molecules, 28(11), 4349. Yu, H., Li, K., Cao, Y., Zhu, Y., Liu, X., & Sun, J. (2022). Synergistic remediation of lead contaminated soil by microbial fuel cell and composite remediation agent. Energy Reports, 8, 388–397. Zaeni, A., Susilowati, P. E., Alwahab, & Ahmad, L. O. (2020). Renewable energy from sediment microbial fuel cell technology from Kendari Bay swamp sediments. AIP Conference Proceedings, Zhang, H., Chao, B., Gao, X., Cao, X., & Li, X. (2022). Effect of starch-derived organic acids on the removal of polycyclic aromatic hydrocarbons in an aquaculture-sediment microbial fuel cell. Journal of Environmental management, 311, 114783. Zhang, J., Cao, X., Wang, H., Long, X., & Li, X. (2020). Simultaneous enhancement of heavy metal removal and electricity generation in soil microbial fuel cell. Ecotoxicology and Environmental Safety, 192, 110314. Zhang, J., Jiao, W., Huang, S., Wang, H., Cao, X., Li, X., & Sakamaki, T. (2022). Application of microbial fuel cell technology to the remediation of compound heavy metal contamination in soil. Journal of Environmental management, 320, 115670. Zhang, J., Liu, Y., Sun, Y., Wang, H., Cao, X., & Li, X. (2020). Effect of soil type on heavy metals removal in bioelectrochemical system. Bioelectrochemistry, 136, 107596. Zhang, Q., Zhang, L., Li, Z., Zhang, L., & Li, D. (2019). Enhancement of fipronil degradation with eliminating its toxicity in a microbial fuel cell and the catabolic versatility of anodic biofilm. Bioresource Technology, 290, 121723. Zhang, Q., Zhang, L., Wang, H., Jiang, Q., & Zhu, X. (2018). Simultaneous efficient removal of oxyfluorfen with electricity generation in a microbial fuel cell and its microbial community analysis. Bioresource Technology, 250, 658–665. Zhao, J., Li, F., Cao, Y., Zhang, X., Chen, T., Song, H., & Wang, Z. (2021). Microbial extracellular electron transfer and strategies for engineering electroactive microorganisms. Biotechnology advances, 53, 107682. Zhao, Q., Bilal, M., Yue, S., Hu, H., Wang, W., & Zhang, X. (2017). Identification of biphenyl 2, 3-dioxygenase and its catabolic role for phenazine degradation in Sphingobium yanoikuyae B1. Journal of Environmental management, 204, 494–501. Zhao, Y., Li, Z., Ma, J., Yun, H., Qi, M., Ma, X., Wang, H., Wang, A., & Liang, B. (2018). Enhanced bioelectroremediation of a complexly contaminated river sediment through stimulating electroactive degraders with methanol supply. Journal of hazardous materials, 349, 168–176. Zhou, H., Xuanyuan, X., Lv, X., Wang, J., Feng, K., Chen, C., Ma, J., & Xing, D. (2023). Mechanisms of magnetic sensing and regulating extracellular electron transfer of electroactive bacteria under magnetic fields. Science of The Total Environment, 895, 165104. Zhou, X., Chen, X., Li, H., Xiong, J., Li, X., & Li, W. (2016). Surface oxygen-rich titanium as anode for high performance microbial fuel cell. Electrochimica acta, 209, 582–590. Zhou, Y.-L., Jiang, H.-L., & Cai, H.-Y. (2015). To prevent the occurrence of black water agglomerate through delaying decomposition of cyanobacterial bloom biomass by sediment microbial fuel cell. Journal of hazardous materials, 287, 7–15. Zhou, Y., Shi, C., Fan, M., Feng, Y., Xu, Y., & Chen, Y. (2019). The efficient biodegradation of dimethyl phthalate using an anaerobic bioelectrochemical system. Journal of Chemical Technology & Biotechnology, 94(9), 2935–2943. Zhu, N., Tang, J., Tang, C., Duan, P., Yao, L., Wu, Y., & Dionysiou, D. D. (2018). Combined CdS nanoparticles-assisted photocatalysis and periphytic biological processes for nitrate removal. Chemical Engineering Journal, 353, 237–245. Zhu, N., Wu, Y., Tang, J., Duan, P., Yao, L., Rene, E. R., Wong, P. K., An, T., & Dionysiou, D. D. (2018). A new concept of promoting nitrate reduction in surface waters: simultaneous supplement of denitrifiers, electron donor pool, and electron mediators. Environmental science & technology, 52(15), 8617–8626. Zhuang, L., Tang, J., Wang, Y., Hu, M., & Zhou, S. (2015). Conductive iron oxide minerals accelerate syntrophic cooperation in methanogenic benzoate degradation. Journal of hazardous materials, 293, 37–45. | ||
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