mcie-rs101
/
poster-example


								@misc{camara2021,

								    title = {Constitución Política de los Estados Unidos Mexicanos, Artículo 4.},

								    author = {Cámara de Diputados},

								    howpublished = {\url{http://www3.diputados.gob.mx/camara/001_diputados/012_comisioneslxii/01_ordinarias/002_agua_potable_y_saneamiento/13_marco_juridico/01_constitucion_politica_de_los_estados_unidos_mexicanos}},

								    year = {2021},

								    note = {Consultado en Agosto 2021}

								}


								@misc{conagua-2011,

								title = {Estadísticas del Agua en México},

								author = {Comisión Nacional del Agua},

								howpublished = {\url{http://www.conagua.gob.mx/CONAGUA07/Publicaciones/Publicaciones/SGP-1-11-EAM2011.PDF}},

								year = {2011},

								note = {Recuperado 8 de agosto de 2021}

								}


								@misc{fondo2021,

								title= {Contaminación en México},

								author = {Fondo para la Comunicación y la Educación Ambiental A.C.},

								howpublished = {\url{https://agua.org.mx/agua-contaminacion-en-mexico/}},

								note = {Recuperado 10 de agosto de 2021}

								}


								@misc{halogen2022,

								title= {Sensor de ORP: Potencial de Oxidación-Reducción},

								author = {Halogen Systems Inc.},

								howpublished = {\url{https://halogensys.com/es/orp-vs-amperometry/}},

								year = {2022},

								note = {Recuperado el 02 de febrero de 2022}

								}


								@article{merida2020,

									title = {Calidad bacteriológica del agua y su relación con el potencial de óxido reducción ({ORP})},

									volume = {15},

									rights = {Derechos de autor 2021},

									issn = {2222-2499},

									url = {https://revistas.usac.edu.gt/index.php/asa/article/view/1130},

									abstract = {This article presents the relationship between the bacteriological quality of water and the oxide-reduction potential ({ORP}) in a water treatment plant. For this, a monitoring it was carry out determining the values of {ORP} and fecal and total coliforms in the fast filtration unit and in the reservoir of drinking water with disinfected water. According to the results obtained, the presence of fecal and total coliforms occurred with average values of oxide-reduction potential ({ORP}) of 250 {mV}, and the absence of these was presented with an average {ORP} of 760 {mV}. The research work showed that there is a relation of presence absence of fecal and total coliforms with respect to the potential of oxide reduction, so it is possible to use this parameter to determine the presence or absence of coliforms in water in a water treatment plant. According to the statistical analysis performed for the data obtained from coliforms in the filtration unit, it was obtained that there is no direct correlation between the {ORP} and fecal and total coliforms, given that the Pearson coefficients found were -0.203, -0.388 with a significance of 0.549 and 0.239 respectively, which shows that there is no statistically significant relationship between these variables. For {ORP} values below 300 {mV}, there is no linear behavior that allows to establish the ratio of fecal and total coliforms with the oxide-reduction potential.},

									pages = {41--47},

									number = {1},

									journaltitle = {Agua, Saneamiento \& Ambiente},

									author = {Cano, Marvin Eduardo Mérida and Carrera, Félix Alan Douglas Aguilar},

									urldate = {2022-06-25},

									date = {2020-12-31},

									langid = {spanish},

									note = {Number: 1},

									keywords = {desinfección},

									file = {Full Text PDF:/Users/gmarx/Zotero/storage/LD3PESYU/Cano and Carrera - 2020 - Calidad bacteriológica del agua y su relación con .pdf:application/pdf},

								}


								@misc{secretaria-salud,

								title= {Anuario de morbilidad 1984-2017,

								Ciudad de México},

								author = {Secretaria de salud},

								howpublished = {\url{http://www.epidemiologia.salud.gob.mx/anuario/html/anuarios.htlm}},

								year = {2018},

								note = {Recuperado en 2022}

								}


								@article{soto2016,

									title = {Panorama epidemiológico de México, principales causas de morbilidad y mortalidad},

									volume = {59},

									issn = {0026-1742},

									url = {http://www.scielo.org.mx/scielo.php?script=sci_abstract&pid=S0026-17422016000600008&lng=es&nrm=iso&tlng=es},

									pages = {8--22},

									number = {6},

									journaltitle = {Revista de la Facultad de Medicina (México)},

									author = {Soto-Estrada, Guadalupe and Moreno-Altamirano, Laura and Pahua Díaz, Daniel and Soto-Estrada, Guadalupe and Moreno-Altamirano, Laura and Pahua Díaz, Daniel},

									urldate = {2022-06-25},

									date = {2016-12},

									langid = {spanish},

									note = {Publisher: Universidad Nacional Autónoma de México, Facultad de Medicina},

									file = {Full Text PDF:/Users/gmarx/Zotero/storage/W3YIGG7E/Soto-Estrada et al. - 2016 - Panorama epidemiológico de México, principales cau.pdf:application/pdf;Snapshot:/Users/gmarx/Zotero/storage/YGMJPNFA/scielo.html:text/html},

								}


								@article{Suslow2004,

									title = {Oxidation-Reduction Potential ({ORP}) for Water Disinfection Monitoring, Control, and Documentation},

									url = {https://escholarship.org/uc/item/1730p498},

									doi = {10.3733/ucanr.8149},

									abstract = {Large volumes of water are commonly used during postharvest handling of minimally processed fruits and vegetables. Water disinfection is a critical step in minimizing the potential transmission of pathogens from a water source to produce.},

									author = {Suslow, Trevor V.},

									urldate = {2022-06-25},

									date = {2004-09-01},

									langid = {english},

									file = {Full Text PDF:/Users/gmarx/Zotero/storage/69NVFLQN/Suslow - 2004 - Oxidation-Reduction Potential (ORP) for Water Disi.pdf:application/pdf;Snapshot:/Users/gmarx/Zotero/storage/25ESUE4B/1730p498.html:text/html},

								}


								@online{undesa2008,

									title = {Population change – Outlook from {UN} {DESA} — European Environment Agency},

									url = {https://www.eea.europa.eu/data-and-maps/indicators/total-population-outlook-from-unstat-2/assessment},

									abstract = {The world’s population increased from 2.5 billion in 1950 to around 7 billion in 2010, and is expected to continue to rise until 2050/2100 under most {UN} projection variants. Assuming the ‘medium fertility’ projection variant, global population might increase to 9.6 billion by 2050, rising to 10.9 billion by 2100. However, if fertility and mortality rates stay at current levels (i.e. assuming the ‘no change’ projection variant), growth rates would be substantially higher, and the global population could rise to 10.2 billion by 2050 and 19.9 billion by 2100.

								 Expected global population growth is projected to be largely driven by increases in Asia and particularly in Africa. While the Asian population is expected to peak by 2050, Africa’s population is projected to grow strongly and continuously, from about 1 billion today to more than 4 billion by 2100, under ‘medium fertility’ assumptions.

								 The total population of the 28 {EU} Member States is projected to slightly increase from the current figure of 505 million to 520 million by 2030, and then to decrease in the subsequent decades to some 475 million by 2100, under ‘medium fertility’ assumptions. The age structure is projected to change substantially, with an increase of the share of people aged 65 years or older from the current figure of 17\% to over 30\% by 2050, under ‘medium fertility’ assumptions.},

									type = {Indicator Assessment},

									urldate = {2022-06-25},

									langid = {english},

									file = {Snapshot:/Users/gmarx/Zotero/storage/4374BP7C/assessment.html:text/html},

									note={Consultado en ...}

								}


								@article{lin2017,

									title = {Multifunctional Water Sensors for {pH}, {ORP}, and Conductivity Using Only Microfabricated Platinum Electrodes},

									volume = {17},

									issn = {1424-8220},

									doi = {10.3390/s17071655},

									abstract = {Monitoring of the {pH}, oxidation-reduction-potential ({ORP}), and conductivity of aqueous samples is typically performed using multiple sensors. To minimize the size and cost of these sensors for practical applications, we have investigated the use of a single sensor constructed with only bare platinum electrodes deposited on a glass substrate. The sensor can measure {pH} from 4 to 10 while simultaneously measuring {ORP} from 150 to 800 {mV}. The device can also measure conductivity up to 8000 μS/cm in the range of 10 °C to 50 °C, and all these measurements can be made even if the water samples contain common ions found in residential water. The sensor is inexpensive (i.e., {\textasciitilde}\$0.10/unit) and has a sensing area below 1 mm², suggesting that the unit is cost-efficient, robust, and widely applicable, including in microfluidic systems.},

									pages = {E1655},

									number = {7},

									journaltitle = {Sensors (Basel, Switzerland)},

									shortjournal = {Sensors (Basel)},

									author = {Lin, Wen-Chi and Brondum, Klaus and Monroe, Charles W. and Burns, Mark A.},

									date = {2017-07-19},

									pmid = {28753913},

									pmcid = {PMC5539692},

									keywords = {conductivity sensor, micro-fabrication, {ORP} sensor, {pH} sensor, water safety},

									file = {Full Text:/Users/gmarx/Zotero/storage/A8GSFNAV/Lin et al. - 2017 - Multifunctional Water Sensors for pH, ORP, and Con.pdf:application/pdf},

								}


								@article{Steininger,

									title = {Water treatment experts are becoming increasingly aware that water disinfection is dependent upon {ORP} and not the free residual chlorine ratio.},

									language = {en},

									author = {Steininger, Jacques M},

									pages = {6},

									file = {Steininger - Water treatment experts are becoming increasingly .pdf:C\:\\Users\\IBARR\\Zotero\\storage\\HJ6XFWLP\\Steininger - Water treatment experts are becoming increasingly .pdf:application/pdf},

								}


								@misc{JoseL-2019,

								title = {Potencial Óxido-Reducción, aproximación a una medida para evaluar la higienización del agua},

								author = {José Luis Vallas García},

								howpublished = {\url{https://avinews.com/potencial-redox-de-oxidacion-reduccion-orp-para-la-bioseguridad-de-nuestras-granjas/?reload=yes}},

								year = {2019},

								note = {Recuperado 23 de febrero de 2023}

								}


								@misc{JuanC-2006,

								title = {El agua en México},

								author = {José Carlos Valencia Vargas},

								howpublished = {\url{http://www.conagua.gob.mx/conagua07/publicaciones/publicaciones/el-agua-en-mexico.pdf}},

								year = {2006},

								note = {Recuperado 25 de febrero de 2023}

								}


								@misc{semar,

								title = {Agua},

								author = {Semarnat},

								howpublished = {\url{https://apps1.semarnat.gob.mx:8443/dgeia/informe_resumen/07_agua/cap7.html}},

								year = {S.f},

								note = {Recuperado 25 de febrero de 2023}

								}