000			02025nam a2200289Ia 4500
001			000008252
003			MX-MdCICY
005			20260112154326.0
008			091210s2010 vaua f p 0|0 | eng d
020			_a9781843393368
040			_cCICY
082	0	4	_a621.042 _bE5 2010
100	1		_aEllis, Michael W.
245	1	0	_aDevelopment of a microbial fuel cell for sustainable wastewater treatment / _cMichael W Ellis, Nancy G Love, Ishwar K Puri
264	3	1	_aAlexandria, VA : _bWater environment research foundation, _c2010
300			_a1 v. (Varias paginaciones) : _bil. ; _c28 cm.
504			_aIncluye referencias bibliográficas
520	3		_aMicrobial Fuel Cells (MiFCs) are a promising renewable energy technology. but suffer from low power densities which hinder their practical applicability. In this work. fíame deposited, carbón nanostructures (CNS) are deposited on a stainless steel mesh anode in an attempt to improve the electrón transfer effíciency from microorganisms to the anode. During experimentation with anaerobic sludge in single-chamber MiFCs, cells utilizing CNS-enhanced anodes generated currents up to two orders of magnitude greater than cells with untreated stainless steel mesh anodes. Average power density with CNS-enhanced anodes was found to be 2 2 300 mW-m" compared to 13.6 mW-m" on untreated stainless steel anodes. Electron microscopy showed that microorganisms were affiliated with the CNS-coated anodes to a much greater degree than the uncoated anodes. In addition, microbial fuel cells using CNS enhanced anodes and nitrifying bacterial cultures were evaluated. With nitrifying bacteria, the MiFC power density was found to be very low.
650	1	4	_aENERGIA BIOMASICA
650	1	4	_aENERGIA RENOVABLE
650	1	4	_aNANOESTRUCTURA
650	1	4	_aNANOTECNOLOGIA
700	1	2	_aLove, Nancy G., _ecoaut.
700	1	2	_aPuri, Ishwar K., _ecoaut.
856	4	0	_uhttps://www.cicy.mx/sitios/sib/doctoelectronico/8252.pdf _zVer tabla de contenido y/o resumen
942			_2ddc _cBK
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