Cathodes as electron donors for microbial metabolism: which extracellular electron transfer mechanisms are involved? M Rosenbaum, F Aulenta, M Villano, LT Angenent Bioresource technology 102 (1), 324-333, 2011 | 655 | 2011 |
Bioelectrochemical reduction of CO< sub> 2</sub> to CH< sub> 4</sub> via direct and indirect extracellular electron transfer by a hydrogenophilic methanogenic culture M Villano, F Aulenta, C Ciucci, T Ferri, A Giuliano, M Majone Bioresource technology 101 (9), 3085-3090, 2010 | 646* | 2010 |
Magnetite particles triggering a faster and more robust syntrophic pathway of methanogenic propionate degradation C Cruz Viggi, S Rossetti, S Fazi, P Paiano, M Majone, F Aulenta Environmental science & technology 48 (13), 7536-7543, 2014 | 629 | 2014 |
Electron transfer from a solid-state electrode assisted by methyl viologen sustains efficient microbial reductive dechlorination of TCE F Aulenta, A Catervi, M Majone, S Panero, P Reale, S Rossetti Environmental science & technology 41 (7), 2554-2559, 2007 | 247 | 2007 |
Electrochemically assisted methane production in a biofilm reactor M Villano, G Monaco, F Aulenta, M Majone Journal of Power Sources 196 (22), 9467-9472, 2011 | 198 | 2011 |
Biotechnologies for Marine Oil Spill Cleanup: Indissoluble Ties with Microorganisms F Mapelli, A Scoma, G Michoud, F Aulenta, N Boon, S Borin, ... Trends in Biotechnology 35 (9), 860-870, 2017 | 192 | 2017 |
Enhanced anaerobic bioremediation of chlorinated solvents: environmental factors influencing microbial activity and their relevance under field conditions F Aulenta, M Majone, V Tandoi Journal of Chemical Technology & Biotechnology: International Research in …, 2006 | 174 | 2006 |
Microbial reductive dechlorination of trichloroethene to ethene with electrodes serving as electron donors without the external addition of redox mediators F Aulenta, A Canosa, P Reale, S Rossetti, S Panero, M Majone Biotechnology and bioengineering 103 (1), 85-91, 2009 | 173 | 2009 |
Carbon and nitrogen removal and enhanced methane production in a microbial electrolysis cell M Villano, S Scardala, F Aulenta, M Majone Bioresource technology 130, 366-371, 2013 | 168 | 2013 |
Linking Bacterial Metabolism to Graphite Cathodes: Electrochemical Insights into the H2‐Producing Capability of Desulfovibrio sp. F Aulenta, L Catapano, L Snip, M Villano, M Majone ChemSusChem 5 (6), 1080-1085, 2012 | 165 | 2012 |
Enhancing methane production from food waste fermentate using biochar: the added value of electrochemical testing in pre-selecting the most effective type of biochar C Cruz Viggi, S Simonetti, E Palma, P Pagliaccia, C Braguglia, S Fazi, ... Biotechnology for biofuels 10, 1-13, 2017 | 160 | 2017 |
Relevance of side reactions in anaerobic reductive dechlorination microcosms amended with different electron donors F Aulenta, A Pera, S Rossetti, MP Papini, M Majone Water Research 41 (1), 27-38, 2007 | 160 | 2007 |
Dechlorination of trichloroethene in a continuous-flow bioelectrochemical reactor: effect of cathode potential on rate, selectivity, and electron transfer mechanisms F Aulenta, L Tocca, R Verdini, P Reale, M Majone Environmental science & technology 45 (19), 8444-8451, 2011 | 140 | 2011 |
Characterization of an electro-active biocathode capable of dechlorinating trichloroethene and cis-dichloroethene to ethene F Aulenta, P Reale, A Canosa, S Rossetti, S Panero, M Majone Biosensors and Bioelectronics 25 (7), 1796-1802, 2010 | 140 | 2010 |
Electrobioremediation of oil spills M Daghio, F Aulenta, E Vaiopoulou, A Franzetti, JBA Arends, A Sherry, ... Water research 114, 351-370, 2017 | 139 | 2017 |
In situ groundwater and sediment bioremediation: barriers and perspectives at European contaminated sites M Majone, R Verdini, F Aulenta, S Rossetti, V Tandoi, N Kalogerakis, ... New biotechnology 32 (1), 133-146, 2015 | 139 | 2015 |
Trichloroethene Dechlorination and H2 Evolution Are Alternative Biological Pathways of Electric Charge Utilization by a Dechlorinating Culture in a … F Aulenta, A Canosa, M Majone, S Panero, P Reale, S Rossetti Environmental science & technology 42 (16), 6185-6190, 2008 | 131 | 2008 |
The humic acid analogue antraquinone-2, 6-disulfonate (AQDS) serves as an electron shuttle in the electricity-driven microbial dechlorination of trichloroethene to cis … F Aulenta, V Di Maio, T Ferri, M Majone Bioresource Technology 101 (24), 9728-9733, 2010 | 119 | 2010 |
Anaerobic arsenite oxidation with an electrode serving as the sole electron acceptor: a novel approach to the bioremediation of arsenic-polluted groundwater N Pous, B Casentini, S Rossetti, S Fazi, S Puig, F Aulenta Journal of hazardous materials 283, 617-622, 2015 | 118 | 2015 |
Microbial electrochemistry for bioremediation X Wang, F Aulenta, S Puig, A Esteve-Núnez, Y He, Y Mu, K Rabaey Environmental Science and Ecotechnology 1, 100013, 2020 | 114 | 2020 |