Peer-Reviewed Publications (since August 2017)
Yadav R., Chattopadhyay B., Kiran R., Yadav A., Bachhawat A.K and Patil S.A. Microbial electrosynthesis from carbon dioxide feedstock linked to yeast growth for the production of high-value isoprenoids. Bioresource Technology, 127906 (2022)
Yadav S. Singh R., Sundharam S.S., Chaudhury S., Krishnamurthi S. and Patil S.A. Geoalkalibacter halelectricus SAP‐1 sp. nov. possessing extracellular electron transfer and mineral‐reducing capabilities from a haloalkaline environment. Environmental Microbiology, 1– 16(2022)
Pant D. and Patil S.A. Microbially catalyzed bioelectrochemical power devices come of age. Joule 6 (7), 1399-1401(2022)
Yadav R., Chiranjeevi P., Yadav S., Singh R. and Patil S.A. Electricity-driven bioproduction
from CO2 and N2 feedstocks using enriched mixed microbial culture. Journal of CO2 Utilization, 60, 101997 (2022)
Roy M., Aryal N., Zhang Y., Patil S.A.* and Pant D. Technological progress and readiness
level of microbial electrosynthesis and electrofermentation for carbon dioxide and organic wastes valorization. Current Opinion in Green and Sustainable Chemistry, 35, 100605 (2022)
Chaudhary S., Yadav S., Singh R., Sadhotra C. and Patil S.A. Extremophilic electroactive microorganisms:
Promising biocatalysts for bioprocessing applications. Bioresource Technology, 347, 126663 (2022)
Singh R., Chaudhary S., Yadav S. and Patil S.A. Protocol for bioelectrochemical enrichment,
cultivation, and characterization of extreme electroactive microorganisms. STAR Protocols, 3(1), 101114 (2022)
Yadav R.K., Sahoo S. and Patil S.A. Performance evaluation of the integrated hydroponics-
microbial electrochemical technology (iHydroMET) for decentralized domestic wastewater
treatment, Chemosphere, 288, 132514 (2022)
Roy M., Yadav S. and Patil S.A. Biogas upgradation through CO2 conversion into acetic acid
via microbial electrosynthesis. Frontiers in Energy Research, 9, 759678 (2021)
Yadav R.K., Sahoo S., Yadav A.K. and Patil S.A. Epipremnum aureum is a promising plant
candidate for developing nature-based technologies for nutrients removal from wastewaters.
Journal of Environmental Chemical Engineering, 9(5), 106134 (2021)
Chaudhary S., Singh, R., Sukrampal and Patil S.A. (2021): Electrochemical enrichment of
haloalkaliphilic nitrate-reducing microbial biofilm at the cathode of bioelectrochemical
systems. iScience, 24 (6), 102682 (2021)
Jiang M., Gao Y., Patil S.A., Hou H., Feng W. and Chen S. Reactive coating modification of
metal material with strong bonding strength and enhanced corrosion resistance for high-
performance bioelectrode of microbial electrochemical technologies. Journal of Power
Sources, 491, 229595 (2021)
Gupta S., Srivasatva P. Patil S.A. and Yadav A.K. A comprehensive review on emerging
constructed wetland coupled microbial fuel cell technology: potential applications and
challenges. Bioresource Technology, 320 (Part B), 124376 (2021)
Roy M. Yadav R. Chiranjeevi P. and Patil S.A. Direct utilization of industrial carbon dioxide with low
impurities for acetate production via microbial electrosynthesis. Bioresource Technology, 124289
(2020).
Yadav S. and Patil S.A. Microbial electroactive biofilms dominated by Geoalkalibacter spp. from a
highly saline–alkaline environment. npj Biofilms Microbiomes 6, 38 (2020).
Das S., Ludo D., Pant D., Patil S.A. and Ghangrekar M.M. Microbial electrosynthesis: A way towards
the production of electro-commodities through carbon sequestration with microbes as biocatalysts.
Journal of the Electrochemical Society 167, 155510 (2020).
Zhao W., Fu W., Chen S., Xiong H., Lan L., Jiang M., Patil S.A. and Chen S. High-capacitance bioanode
circumvents bioelectrochemical reaction transition in the voltage-reversed serially-stacked air-
cathode microbial fuel cell. Journal of Power Sources 468, 228402 (2020).
Kumar R., Yadav S. and Patil S.A. Bioanode-assisted removal of Hg2+ at the cathode of microbial fuel
cells. Journal of Hazardous, Toxic, and Radioactive Waste 24 (4), 04020034 (2020)
Chiranjeevi P., *Patil S.A., Microbial fuel cell coupled with microalgae cultivation
for wastewater treatment and energy recovery. Integrated Microbial Fuel Cells for Wastewater Treatment, 213-227, 2020.
Sukrampal, Kumar R., *Patil S.A., Removal of heavy metals using bioelectrochemical systems.
Integrated Microbial Fuel Cells for Wastewater Treatment, 49-71, 2020.
Yadav R.K., Chiranjeevi P., Sukrampal, *Patil S.A., Integrated drip hydroponics-microbial fuel
cell system for wastewater treatment and resource recovery. Bioresource Technology Reports, 9, 100392, 2020.
Chiranjeevi P. and *Patil S.A., Strategies for improving the electroactivity and specific
metabolic functionality of microorganisms for various microbial electrochemical
technologies. Biotechnology Advances, 39, 107468, 2020.
Moss, C., Patil S.A., and Schröder, U., Scratching the surface – How decisive are
microscopic surface structures on growth and performance of electrochemically active
bacteria? Frontiers in Energy Research 7 (Article 18), 1-10, 2019.
Kiran R. and *Patil S.A., Microbial electroactive biofilms, In Introduction to Biofilm
Engineering, Chapter 8, pp 159-186, ACS Symposium Series, Vol. 1323, Publisher –
ACS, 2019.
Chiranjeevi P., Bulut M. Breugelmans T., Patil S.A. and Pant, D., Current Trends in
Enzymatic Electrosynthesis for CO 2 Reduction. Current Opinion in Green and Sustainable
Chemistry 16, 65-70, 2019.
Chen S., Brown R.K., Patil S.A., Huber K.J., Overmann J., Schröder U., Aerobic
microbial electrochemical technology based on the coexistence and interactions of
aerobes and exoelectrogens for synergistic pollutant removal from wastewater,
Environmental Science: Water Research and Technology 5, 60-69, 2019.
Rivera I., Schröder U., *Patil S.A., Microbial Electrolysis for Biohydrogen Production:
Technical Aspects and Scale-Up Experiences, In Microbial Electrochemical Technology:
Sustainable Platform for Fuels, Chemicals and Remediation, Pages 871-898, Publisher –
Elsevier, 2019.
Chen S., *Patil S.A., Brown R.K., Schröder U., Strategies for optimizing the power
output of microbial fuel cells: Transitioning from fundamental studies to practical
implementation, Applied Energy 233, 15-28, 2019.
Mateos R., Escapa A., Vanbroekhoven K., Patil S.A., Moran A., Pant, D., Microbial
Electrochemical Technologies for CO 2 and Its Derived Products Valorization, In
Microbial Electrochemical Technology: Sustainable Platform for Fuels, Chemicals and
Remediation, Pages 777-796, Publisher – Elsevier, 2019.
Chen S., Patil S.A., Schröder U., Substrate Crossover Effect and Performance
Regeneration of the Biofouled Rotating Air-Cathode in Microbial Fuel Cell, Frontiers in
Energy Research 6 (Article 85), 1-7, 2018.
Wu, S., Patil, S.A. and Chen S., Auto-feeding microbial fuel cell inspired by transpiration
of plants. Applied Energy 225, 934-939, 2018.
Sonawane, J.M., Patil, S.A., Ghosh, P.C. and Adeloju, S.B., Low-cost stainless-steel wool
anodes modified with polyaniline and polypyrrole for high-performance microbial fuel
cells. Journal of Power Sources, 389, 103-114, 2018.
Chen S., Patil, S.A. and Schröder U., A high-performance rotating graphite fiber brush
air-cathode for microbial fuel cells. Applied Energy, 211, 1089-1094, 2018.
Seelam J.S., Maesara S.A., Gunda M., Patil S.A., ter Heijne A., Pant D., Resource
recovery from wastes and wastewaters using microbial bioelectrochemical systems. In
Waste Biorefinery: Potential and Perspectives, Pages 535-570, Publisher – Elsevier, 2018.
Aryal, N., Ammam, F., *Patil, S.A. and Pant, D., An overview of cathode materials for
microbial electrosynthesis of chemicals from carbon dioxide. Green Chemistry, 19, 5748-
5760, 2017.
* Corresponding author
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