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zot_bibli.bib
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@article{alvaradoElectrodeionizationPrinciplesStrategies2014,
title = {Electrodeionization: {{Principles}}, {{Strategies}} and {{Applications}}},
shorttitle = {Electrodeionization},
author = {Alvarado, Luc{\'i}a and Chen, Aicheng},
year = {2014},
month = jun,
journal = {Electrochimica Acta},
volume = {132},
pages = {583--597},
issn = {0013-4686},
doi = {10.1016/j.electacta.2014.03.165},
urldate = {2023-06-10},
abstract = {Electrodeionization is an ionic separation technology that initially emerged {$\sim$}50 years ago. In an early application, it was utilized to remove metallic species from radioactive wastewater; however, a poor understanding of its functional kinetics has slowed its development and applications. Steadily increasing research efforts have focused on the elucidation of detailed operational mechanisms, thereby enabling the extension of its applications to other fields. To date, electrodeionization has been proven to be an excellent environmentally compatible purification, separation and concentration method. Novel materials have been continuously developed toward the improvement and maturation of this technology, which may lead to enormous environmental and economic benefits on a global scale. This comprehensive review examines the inception, precursor techniques and historic evolution of electrodeionization, as well as its underlying principles, advantages and promising applications in wastewater treatment and water purification.},
langid = {english},
keywords = {Electrodeionization,Electrodialysis,Ion exchange,Membranes,Water purification}
}
@incollection{b.siziriciyildizWaterWastewaterTreatment2012,
title = {Water and Wastewater Treatment: Biological Processes},
shorttitle = {Water and Wastewater Treatment},
booktitle = {Metropolitan {{Sustainability}}},
author = {{B. Sizirici Yildiz}},
year = {2012},
month = jan,
pages = {406--428},
publisher = {{Woodhead Publishing}},
doi = {10.1533/9780857096463.3.406},
urldate = {2023-06-11},
abstract = {Population growth in urban areas is leading to an expansion in industrial development, which in turn creates increased volumes of wastewater with ever\ldots},
isbn = {978-0-85709-646-3},
langid = {english},
file = {C\:\\Users\\User\\Zotero\\storage\\THLYJWMI\\B9780857090461500187.html}
}
@misc{elgalabwaterImpactoCompuestosInorganicos2018,
title = {Impacto de Los Compuestos Inorg\'anicos | {{Impurezas}} En El Agua},
author = {{ELGA LabWater}},
year = {2018},
urldate = {2023-06-11},
url = {https://es.elgalabwater.com/inorganic-compounds},
file = {C\:\\Users\\User\\Zotero\\storage\\P6HCE4Y5\\inorganic-compounds.html}
}
@misc{elgalabwaterImpactoCompuestosOrganicos2018,
title = {Impacto de Los Compuestos Org\'anicos | {{Impurezas}} En El Agua},
author = {{ELGA LabWater}},
year = {2018},
urldate = {2023-06-11},
url = {https://es.elgalabwater.com/organic-compounds},
file = {C\:\\Users\\User\\Zotero\\storage\\LIWSUYRA\\organic-compounds.html}
}
@techreport{farm.veronicamartinezFARMACOPEAS2005,
title = {{{FARMACOPEAS}}},
author = {{Farm. Ver\'onica Martinez}},
year = {2005}
}
@misc{higieneambientalHistoriaTratamientoAgua2018,
title = {La Historia Del Tratamiento Del Agua Potable: Un Camino Hacia La Mejora Radical de La Salud P\'ublica | {{Higiene Ambiental}}},
author = {{Higieneambiental}},
year = {2018},
urldate = {2023-06-11},
abstract = {El agua es fuente de vida... pero tambi\'en puede ser el medio m\'as eficiente para transmitir r\'apidamente pat\'ogenos. La cloraci\'on, desde principios del siglo XX, ha reducido dr\'asticamente la incidencia de las principales enfermedades transmitidas por el agua. Pero diversos tratamientos del agua se iniciaron ya miles de a\~nos antes, y han evolucionado hasta conseguir lo que ahora nos parece obvio: un grifo del que brota continuamente agua potable.},
url = {https://higieneambiental.com/aire-agua-y-legionella/la-historia-del-tratamiento-del-agua-potable-un-camino-hacia-la-mejora-radical-de-la-salud-publica},
file = {C\:\\Users\\User\\Zotero\\storage\\HFGXGNPV\\la-historia-del-tratamiento-del-agua-potable-un-camino-hacia-la-mejora-radical-de-la-salud-publ.html}
}
@misc{ispeGoodManufacturingPractice,
title = {Good {{Manufacturing Practice}} ({{GMP}}) {{Resources}} | {{ISPE}} | {{International Society}} for {{Pharmaceutical Engineering}}},
author = {{ISPE}},
urldate = {2023-06-11},
url = {https://ispe.org/initiatives/regulatory-resources/gmp},
file = {C\:\\Users\\User\\Zotero\\storage\\SUS3WPYV\\gmp.html}
}
@misc{juanantoniodelacuerdaImportanciaAguaIndustria2021,
title = {La Importancia Del Agua En La Industria Farmac\'eutica},
author = {{Juan Antonio de la Cuerda}},
year = {2021},
urldate = {2023-06-11},
url = {https://revistas.eleconomista.es/agua/2021/diciembre/la-importancia-del-agua-en-la-industria-farmaceutica-YA9763706},
file = {C\:\\Users\\User\\Zotero\\storage\\GQ2CNF8D\\la-importancia-del-agua-en-la-industria-farmaceutica-YA9763706.html}
}
@article{kayayAdvancesRealtimeMonitoring2020,
title = {Advances in Real-Time Monitoring of Water and Wastewater Treatment Processes: {{A}} Review},
author = {{Kaya, Y} and {Ak\c{c}a, L}},
year = {2020},
journal = {Journal of Water Process Engineering},
volume = {38},
pages = {2545--2602}
}
@misc{luiscarrascoQueTipoImpurezas2021,
title = {Que Tipo de Impurezas Podemos Encontrar En El Agua? \textendash{} {{Breve}} Con {{Sejo}}},
author = {{Luis Carrasco}},
year = {2021},
urldate = {2023-05-11},
url = {https://breveconsejo.com.mx/que-tipo-de-impurezas-podemos-encontrar-en-el-agua/}
}
@misc{mireyadelpilararcospulidoIndicadoresMicrobiologicosContaminacion2015,
title = {Indicadores Microbiol\'ogicos de Contaminaci\'on de Las Fuentes de Agua},
author = {{Mireya del Pilar Arcos Pulido} and {Sara Lilia \'Avila de Navia} and {Sandra M\'onica Estupi\~n\'an Torres} and {Aura Cristina G\'omez Prieto}},
year = {2015},
urldate = {2023-04-01},
abstract = {El crecimiento de la poblaci\'on a nivel mundial ha incrementado los niveles de contaminaci\'on. Esta contaminaci\'on est\'a relacionada con el vertido de agua de desecho de origen dom\'estico e industrial a los cuerpos de agua. En el caso de los residuos de origen dom\'estico, la carga contaminante est\'a representada por altos porcentajes de materia org\'anica y microorganismos de origen fecal. El control de la calidad microbiol\'ogica del agua de consumo y de desecho, requiere de an\'alisis dirigidos a determinar la presencia de microorganismos pat\'ogenos; los agentes involucrados en la transmisi\'on h\'idrica son las bacterias, virus y protozoos, que pueden causar enfermedades con diferentes niveles de gravedad, desde gastroenteritis simple hasta casos fatales de diarrea, disenter\'ia, hepatitis o fiebre tifoidea. El diagn\'ostico de estos microorganismos, requiere laboratorios especializados y representa varios d\'ias de an\'alisis y costos elevados. Como alternativa a estos inconvenientes, se ha propuesto el uso de indicadores microbianos que se puedan identificar mediante el uso de m\'etodos sencillos, r\'apidos y econ\'omicos. El diagn\'ostico y posterior recuperaci\'on de las fuentes de agua naturales contaminadas, debe hacerse adem\'as, teniendo en cuenta las implicaciones que en t\'erminos ecol\'ogicos y sanitarios representa la degradaci\'on del recurso. En este sentido, las microalgas perifiticas se constituyen como buenos indicadores del estado tr\'ofico de los ecosistemas y responden a los disturbios ocurridos modificando su estructura en cuanto a composici\'on y abundancia se refiere. Este trabajo hace una revisi\'on de los principales bioindicadores de contaminaci\'on y su significado en la evaluaci\'on de la calidad del agua.},
url = {https://www.researchgate.net/publication/316949337\_Indicadores\_microbiologicos\_de\_contaminacion\_de\_las\_fuentes\_de\_agua},
file = {C\:\\Users\\User\\Zotero\\storage\\YREKR93A\\316949337_Indicadores_microbiologicos_de_contaminacion_de_las_fuentes_de_agua.html}
}
@misc{oceanebidaultQueFactoresDeterminan,
title = {{\textquestiondown Qu\'e factores determinan la calidad del agua?}},
author = {{Oc\'eane Bidault}},
journal = {Waterlogic},
urldate = {2023-05-18},
abstract = {La calidad de agua se mide con factores qu\'imicos, f\'isicos, biol\'ogicos y bacteriol\'ogicos pero el nivel de dureza es un par\'ametros importante},
url = {https://www.waterlogic.es/blog/que-factores-determinan-la-calidad-del-agua/},
langid = {spanish},
file = {C\:\\Users\\User\\Zotero\\storage\\J3IDG4D5\\que-factores-determinan-la-calidad-del-agua.html}
}
@article{quxApplicationsNanotechnologyWater2013,
title = {Applications of Nanotechnology in Water and Wastewater Treatment. {{Water Research}}},
author = {{Qu, X} and {Alvarez, P} and {Li, Q}},
year = {2013},
journal = {Water Research},
volume = {47},
number = {12},
pages = {3931--3946}
}
@misc{setaphtTratamientosAguaPara,
title = {Tratamientos de Agua Para Usos Farmac\'euticos},
author = {{Setapht}},
urldate = {2023-06-02},
url = {https://www.setapht.com/blog/tratamientos-de-agua-para-usos-farmaceuticos/},
file = {C\:\\Users\\User\\Zotero\\storage\\8PD6LT8K\\tratamientos-de-agua-para-usos-farmaceuticos.html}
}
@misc{condorchemUltrapureWaterElectrodeionization2019,
title = {Ultrapure Water by Electrodeionization},
author = {{Condorchem}},
year = {2019},
month = dec,
journal = {Condorchem Envitech},
urldate = {2023-06-12},
abstract = {Electrodeionization (EDI) is a technology that combines two water purification techniques, electrodialysis and ion exchange, to produce ultrapure water.},
url = {https://condorchem.com/en/blog/ultrapure-water-electrodeionization/},
langid = {english},
file = {C\:\\Users\\User\\Zotero\\storage\\MGNL2RMF\\ultrapure-water-electrodeionization.html}
}
@misc{dupontElectrodeionizationEDI,
title = {Electrodeionization ({{EDI}})},
author = {{Dupont}},
urldate = {2023-06-12},
abstract = {Electrodeionization (EDI) is a continuous, chemical-free process of removing ionized and ionizable species from feedwater using DC power. Learn more.},
url = {https://www.dupont.com/water/technologies/electrodeionization-edi.html},
langid = {american},
file = {C\:\\Users\\User\\Zotero\\storage\\D7XP2XNF\\electrodeionization-edi.html}
}
@article{Electrodesionizacion2023,
title = {{Electrodesionizaci\'on}},
year = {2023},
month = may,
journal = {Wikipedia, la enciclopedia libre},
urldate = {2023-06-12},
abstract = {La electrodesionizaci\'on (EDI) es una tecnolog\'ia h\'ibrida de purificaci\'on de agua consiguiendo un alto grado de pureza. Consiste en la combinaci\'on del m\'etodo de intercambio de iones con la electrodi\'alisis, para eliminar las impurezas (iones disueltos). Es un proceso similar a la electrodi\'alisis, se aplica corriente el\'ectrica continua a los electrodos, pero en el caso de la EDI hay membranas semipermeables al paso de iones entre las cuales existe una resina de intercambio i\'onico. Recibe mucha atenci\'on debido a que no necesita qu\'imicos para la regeneraci\'on de resinas. La aplicaci\'on m\'as com\'un de la electrodesionizaci\'on es el tratamiento de agua para obtener un alto grado de pureza, con una conductividad inferior a 0.1 {$\mu$}S/cm[1]\hspace{0pt} y una resistencia el\'ectrica en un rango de 8-17 M{$\Omega$}M gracias a su elevada eficiencia. gracias a su elevada eficiencia. La electrodesionizaci\'on suele encontrarse tras un proceso de \'Osmosis Inversa (RO) como tratamiento de pulido y, a diferencia de otros m\'etodos, no requiere de tratamientos qu\'imicos, lo que permite que la unidad opere en r\'egimen continuo. Por esta raz\'on, el proceso de electrodesionizaci\'on tambi\'en es conocido como Electrodesionizaci\'on Continua (CEDI).},
copyright = {Creative Commons Attribution-ShareAlike License},
langid = {spanish},
annotation = {Page Version ID: 151338878},
file = {C\:\\Users\\User\\Zotero\\storage\\QASZ67P3\\Electrodesionización.html}
}
@misc{lenntechElectrodeionizationEDI,
title = {Electrodeionization ({{EDI}})},
author = {{Lenntech}},
journal = {Electrodeionization (EDI) - Lenntech},
urldate = {2023-06-12},
url = {https://www.lenntech.com/library/edi/edi.htm},
file = {C\:\\Users\\User\\Zotero\\storage\\9BMQCYYV\\edi.html}
}
@misc{nogueraResinasIntercambioIonico,
title = {{Resinas de intercambio i\'onico: Definici\'on y usos}},
shorttitle = {{Resinas de intercambio i\'onico}},
author = {Noguera, Ing Bulmaro},
journal = {Ingenier\'ia Qu\'imica Reviews},
urldate = {2023-06-12},
abstract = {En este art\'iculo describiremos a las resinas de intercambio i\'onico y sus principales usos.},
langid = {spanish},
url = {https://www.ingenieriaquimicareviews.com/2021/09/resinas.html},
file = {C\:\\Users\\User\\Zotero\\storage\\2M4IK6HR\\resinas.html}
}
@article{rasSamplingPreconcentrationTechniques2009,
title = {Sampling and Preconcentration Techniques for Determination of Volatile Organic Compounds in Air Samples},
author = {Ras, Maria Rosa and Borrull, Francesc and Marc{\'e}, Rosa Maria},
year = {2009},
month = mar,
journal = {TrAC Trends in Analytical Chemistry},
volume = {28},
number = {3},
pages = {347--361},
issn = {0165-9936},
doi = {10.1016/j.trac.2008.10.009},
urldate = {2023-06-12},
abstract = {Because air is complex and heterogeneous, continuously evolving in time and space and being influenced by atmospheric and geographical conditions, sampling is crucial in air analysis. Moreover, due to the low levels of pollutants present in the atmosphere, enrichment is often required. This review deals with the most common techniques for sampling and preconcentration of volatile organic compounds (VOCs) in air samples (e.g., whole-air collection in containers, which is usually combined with preconcentration step, and solid-sorbent enrichment methods). We also describe solid sorbents used to trap VOCs in air, and subsequent desorption techniques. In recent years, there have been many efforts to improve on-line analysis methods, which offer real-time data and are useful in providing rapid results. We examine the application of sorbent trapping to on-line analysis and other techniques for on-line analysis (e.g., membrane extraction and selected-ion-flow-tube mass spectrometry).},
langid = {english},
keywords = {Desorption,Enrichment,Membrane extraction,On-line monitoring,Preconcentration,Sampling,Selected-ion-flow-tube mass spectrometry,Sorbent trapping,Volatile organic compound,Whole-air collection},
file = {C\:\\Users\\User\\Zotero\\storage\\G55QCLTF\\S0165993608002380.html}
}
@article{ruiz-jimenezComparisonMultipleCalibration2020,
title = {Comparison of Multiple Calibration Approaches for the Determination of Volatile Organic Compounds in Air Samples by Solid Phase Microextraction {{Arrow}} and In-Tube Extraction},
author = {{Ruiz-Jimenez}, Jose and Lan, Hangzhen and Leleev, Yevgeny and Hartonen, Kari and Riekkola, Marja-Liisa},
year = {2020},
month = apr,
journal = {Journal of Chromatography A},
volume = {1616},
pages = {460825},
issn = {0021-9673},
doi = {10.1016/j.chroma.2019.460825},
urldate = {2023-06-12},
abstract = {Several calibration approaches were evaluated for the quantitation of volatile organic compounds in air using miniaturized exhaustive and non-exhaustive sampling techniques, such as in-tube extraction (ITEX) and solid phase microextraction (SPME) Arrow. Eleven compounds, 2-ethyl-hexanol, hexanal, nonanal, toluene, ethyl-benzene, methyl isobutyl ketone, acetophenone, p-cymene, {$\alpha$}-pinene, trimethylamine and triethylamine, all them found in the natural air samples, were selected as model analytes. Liquid injection, liquid standard addition to the sorbent bed and gas phase standards provided by an automatic permeation system, were evaluated in the case of ITEX packed with laboratory-made 10 percent polyacrylonitrile (PAN) material. Two different approaches, based on sampling of gas phase compounds from the permeation system and from sample vial containing gas phase standards, were evaluated for SPME Arrow with two different coatings, commercial divinylbenzene-poly(dimethylsiloxane) (DVB-PDMS) and laboratory-made mesoporous Mobil Composition of Matter No. 41 (MCM-41). In addition, interface model approach was used for the calculation of the real concentration of the target analytes in the sample from the total amount of analytes injected into the GC\textendash MS in the case of SPME Arrow. Similar results were obtained with the different approaches used for the quantitation by ITEX and SPME Arrow. However, the use of gas phase standards with sample matrix similar to the natural samples, allowed the permeation system to provide the most reliable results for the quantitation of the target analytes. For this approach, linearity (expressed as r2 values) ranged between 0.991 and 0.999. The limit of detection ranged from 0.5~\textmu g/m3 (trimethylamine, MCM-41) to 2.2~\texttimes ~10-4~\textmu g/m3 (methyl isobutyl ketone, MCM-41). In addition, the use of the fully automated permeation system provided good reproducibility values that were between 1.4 percent (acetophenone, MCM-41) and 7.8 percent (methyl isobutyl ketone, 10 percent PAN). The linear ranges were at least 3 order of magnitude for all the studied analytes with the exception of the calibration curve developed for trimethylamine with SPME Arrow (linear ranges between LOQ and 4.9~\textmu g/m3 (DVB-PDMS) and LOQ and 9.8~\textmu g/m3 (MCM-41)).},
langid = {english},
keywords = {Air samples,Calibration,Interface model,ITEX,Permeation system,SPME Arrow},
file = {C\:\\Users\\User\\Zotero\\storage\\2D9C88D8\\Ruiz-Jimenez et al. - 2020 - Comparison of multiple calibration approaches for .pdf;C\:\\Users\\User\\Zotero\\storage\\5DXJXLLH\\S0021967319312968.html}
}
@misc{endress+hauserAnalogConductivitySensor,
title = {Analog Conductivity Sensor {{Condumax CLS16}}},
author = {Endress+Hauser},
year = {2023},
urldate = {2023-06-12},
abstract = {Condumax CLS16 is a high-end conductivity sensor with certified hygienic design. It measures with highest precision providing you with reliable data for optimum process and product quality. Numerous certificates and various hygienic process connections ensure the perfect fit for your process.},
url = {https://www.endress.com/en/field-instruments-overview/liquid-analysis-product-overview/conductivity-conductive-sensor-cls16?t.tabId=product-overview},
langid = {english},
file = {C\:\\Users\\User\\Zotero\\storage\\26NTCKQM\\conductivity-conductive-sensor-cls16.html}
}
@misc{endress+hauserTechnicalInformationOrbisint,
title = {Technical {{Information Orbisint CPS11}} and {{CPS11D}}},
author = {Endress+Hauser},
year = {2023},
url = {https://portal.endress.com/wa001/dla/5000184/5413/000/02/TI028CEN_0208.pdf},
abstract = {pH electrodes, analog or with digital Memosens technology For standard applications in process and environment technology, with dirt-repellent PTFE diaphragm, optional built-in temperature sensor},
langid = {english}
}