Photocatalytic decolorization of Remazol Black 5 and Remazol Brilliant Orange 3R by mesoporous TiO₂CHEN, Chia-Yun; CHENG, Meng-Cheng; CHEN, Arh-Hwang et al.Journal of environmental management. 2012, Vol 102, pp 125-133, issn 0301-4797, 9 p.Article

Geobacter sulfurreducens can grow with oxygen as a terminal electron acceptorLIN, W. C; COPPI, M. V; LOVLEY, D. R et al.Applied and environmental microbiology (Print). 2004, Vol 70, Num 4, pp 2525-2528, issn 0099-2240, 4 p.Article

Operation performance and microbial community dynamics of phosphorus removal sludge with different electron acceptorsXIAOMEI LV; MINGFEI SHAO; CHAOLIN LI et al.Journal of industrial microbiology & biotechnology. 2014, Vol 41, Num 7, pp 1099-1108, issn 1367-5435, 10 p.Article

Evaluating microbial chemical choices: The ocean chemistry basis for the competition between use of O₂ or NO^-₃ as an electron acceptorBREWER, Peter G; HOFMANN, Andreas F; PELTZER, Edward T et al.Deep-sea research. Part 1. Oceanographic research papers. 2014, Vol 87, pp 35-42, issn 0967-0637, 8 p.Article

Effects of azide on electron transport of exoelectrogens in air-cathode microbial fuel cellsXIANGTONG ZHOU; YOUPENG QU; BYUNG HONG KIM et al.Bioresource technology. 2014, Vol 169, pp 265-270, issn 0960-8524, 6 p.Article

Reactive oxygen species (ROS) generated by cyanobacteria act as an electron acceptor in the biocathode of a bio-electrochemical systemCAI, Pei-Jie; XIANG XIAO; HE, Yan-Rong et al.Biosensors & bioelectronics. 2013, Vol 39, Num 1, pp 306-310, issn 0956-5663, 5 p.Article

Reaction of hydroxide ion with electron acceptors in acetonitrileUMEMOTO, K.Chemistry Letters. 1985, Num 9, pp 1415-1418, issn 0366-7022Article

Nitrate is a preferred electron acceptor for growth of freshwater selenate-respiring bacteriaSTEINBERG, N. A; BLUM, J. S; HOCHSTEIN, L et al.Applied and environmental microbiology (Print). 1992, Vol 58, Num 1, pp 426-428, issn 0099-2240Article

Dissimilatory Reduction of Extracellular Electron Acceptors in Anaerobic RespirationRICHTER, Katrin; SCHICKLBERGER, Marcus; GESCHER, Johannes et al.Applied and environmental microbiology (Print). 2012, Vol 78, Num 4, pp 913-921, issn 0099-2240, 9 p.Article

Anaerobic growth of microorganisms with chlorate as an electron acceptorMALMQVIST, A; WELANDER, T; GUNNARSSON, L et al.Applied and environmental microbiology (Print). 1991, Vol 57, Num 8, pp 2229-2232, issn 0099-2240Article

Behavioral response of dissimilatory perchlorate-reducing bacteria to different electron acceptorsSUN, Yvonne; GUSTAVSON, Ruth L; ALI, Nadia et al.Applied microbiology and biotechnology. 2009, Vol 84, Num 5, pp 955-963, issn 0175-7598, 9 p.Article

High electron-acceptability of a 2,2-bis(alkyl- or arylsulfonyl)ethenyl groupOGURA, K; TAKAHASHI, S; KAWAMOTO, Y et al.Tetrahedron letters. 1993, Vol 34, Num 16, pp 2649-2652, issn 0040-4039Article

Photoosmosis through liquid membrane bilayers: studies on chloroplast extract, haemoglobin, protoporphyrin, and cyanocobalaminSRIVASTAVA, R. C; TANDON, A; SHARMA, R. K et al.Journal of colloid and interface science. 1984, Vol 99, Num 1, pp 71-79, issn 0021-9797Article

Preferential Use of an Anode as an Electron Acceptor by an Acidophilic Bacterium in the Presence of OxygenMALKI, Moustafa; DE LACEY, Antonio L; RODRIGUEZ, Nuria et al.Applied and environmental microbiology (Print). 2008, Vol 74, Num 14, pp 4472-4476, issn 0099-2240, 5 p.Article

Wechselwirkungen von Huminstoffen mit Peptiden = Interactions des substances humiques et des peptides = Interactions of humic substances with peptidesMÜLLER-WEGENER, U.Zeitschrift für Pflanzenernährung und Bodenkunde. 1984, Vol 147, Num 1, pp 110-124, issn 0044-3263Article

Removal of Hg²⁺ as an electron acceptor coupled with power generation using a microbial fuel cellZEJIE WANG; LIM, Bongsu; CHOI, Chansoo et al.Bioresource technology. 2011, Vol 102, Num 10, pp 6304-6307, issn 0960-8524, 4 p.Article

Acetaldehyde mediates growth stimulation of ethanol-stressed Saccharomyces cerevisiae: evidence of a redox-driven mechanismVRIESEKOOP, Frank; BARBER, Andrew R; PAMMENT, Neville B et al.Biotechnology letters. 2007, Vol 29, Num 7, pp 1099-1103, issn 0141-5492, 5 p.Article

The ESR study of chemical interactions in triple solid silver-carbon tetrachloride-mesogenic cyanobiphenyl co-condensate systemTIMOSHENKO, V. A; SHABATINA, T. I; BELYAEV, A. A et al.Applied surface science. 2005, Vol 246, Num 4, pp 420-424, issn 0169-4332, 5 p.Article

2,3,5-Triphenyltetrazolium chloride (TTC) as electron acceptor of culturable soil bacteria, fungi and actinomycetesPRAVEEN-KUMAR; TARAFDAR, J. C.Biology and fertility of soils. 2003, Vol 38, Num 3, pp 186-189, issn 0178-2762, 4 p.Article

Cathodic reduction of hexavalent chromium [Cr(VI)] coupled with electricity generation in microbial fuel cellsGANG WANG; LIPING HUANG; YIFENG ZHANG et al.Biotechnology letters. 2008, Vol 30, Num 11, pp 1959-1966, issn 0141-5492, 8 p.Article

Anaerobic biodegradation of polycyclic aromatic hydrocarbons with amendment of iron(III) in mangrove sediment slurryLI, Chun-Hua; WONG, Yuk-Shan; TAM, Nora Fung-Yee et al.Bioresource technology. 2010, Vol 101, Num 21, pp 8083-8092, issn 0960-8524, 10 p.Article

Suppression of anaerobic ammonium oxidizers under high organic content in high-rate Anammox UASB reactorTANG, Chong-Jian; PING ZHENG; WANG, Cai-Hua et al.Bioresource technology. 2010, Vol 101, Num 6, pp 1762-1768, issn 0960-8524, 7 p.Article

Persulfate: A self-activated cathodic electron acceptor for microbial fuel cellsJUN LI; QIAN FU; QIANG LIAO et al.Journal of power sources (Print). 2009, Vol 194, Num 1, pp 269-274, issn 0378-7753, 6 p.Article

DIRECT MEASUREMENT OF THE REDOX POTENTIAL OF THE PRIMARY AND SECONDARY QUINONE ELECTRON ACCEPTORS IN RHODOPSEUDOMONAS SHAEROIDES (WILD-TYPE) BY EPR SPECTROMETRYRUTHERFORD AW; EVANS MCW.1980; F.E.B.S. LETTERS; NLD; DA. 1980; VOL. 110; NO 2; PP. 257-261; BIBL. 21 REF.Article

Oxidation of Q_A^- and of Q_B^- of photosynthetic reaction centers by an artificial acceptorAGALIDIS, I; VELTHUYS, B. R.FEBS letters. 1986, Vol 197, Num 1-3, pp 263-266, issn 0014-5793Article