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@ -144,14 +136,14 @@
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@ -187,16 +177,15 @@
language = {en},
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@ -206,28 +195,27 @@
language = {en},
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@ -239,15 +227,14 @@
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@ -258,15 +245,14 @@
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title = {An analytical formula for determining the electrical impedance between a single adherent cell and sensor substrate},
An analytical formula for the electrical impedance between an adherent living cell and a sensor substrate measured using a microelectrode is presented for the first time. Previously-reported formula has been applicable only for the case where many cells are on a large electrode. In contrast, our formula is valid even when a microelectrode smaller than the cell-size is underneath the cell, which is often the case for the state-of-the-art single-cell analysis. Numerical simulations for verifying the accuracy of our formula reveals that the discrepancies between the theoretical impedances calculated by our formula and numerical simulation results are negligibly small. Our formula will be useful for describing cell-substrate impedance properties in equivalent circuit model analysis or sensor design optimizations.},
abstract = {Abstract An analytical formula for the electrical impedance between an adherent living cell and a sensor substrate measured using a microelectrode is presented for the first time. Previously-reported formula has been applicable only for the case where many cells are on a large electrode. In contrast, our formula is valid even when a microelectrode smaller than the cell-size is underneath the cell, which is often the case for the state-of-the-art single-cell analysis. Numerical simulations for verifying the accuracy of our formula reveals that the discrepancies between the theoretical impedances calculated by our formula and numerical simulation results are negligibly small. Our formula will be useful for describing cell-substrate impedance properties in equivalent circuit model analysis or sensor design optimizations.},
language = {en},
number = {11},
urldate = {2026-01-29},
@ -351,10 +332,9 @@
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language = {Español},
school = {Universidad de Sevilla},
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author = {Guerra, D Carlos Fúnez and Clemente, M. del Carmen and {Funez Guerra, Carlos}},
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month = dec,
year = {2024},
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@ -533,10 +503,9 @@
month = feb,
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@ -567,10 +535,9 @@
month = jun,
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address = {Hoboken, NJ, USA},
edition = {Third edition},
title = {Fuel cell systems explained},
isbn = {978-1-118-70697-8 978-1-118-70699-2 978-1-118-70696-1 978-1-118-70698-5 978-1-5231-2355-1},
language = {en},
publisher = {Wiley},
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file = {PDF:/Users/mguillermo/Zotero/storage/3XDVW6J9/Dicks and Rand - 2018 - Fuel cell systems explained.pdf:application/pdf},
@ -42,7 +42,7 @@ Las emisiones de gases de efecto invernadero provocadas por las actividades huma
La electrólisis es un proceso electroquímico por el cual se puede realizar la separación de la molécula del agua ($H_2O$) en sus dos elementos básicos $H_2$ y $O$, creando asi una reacción de oxido-reducción [@ref24]. Este fenómeno ocurre en una celda electroquímica, donde se aplica una diferencia de potencial entre dos electrodos sumergidos en un electrolito, lo que promueve el transporte iónico y la transferencia de carga en las interfaces electrodo-electrolito, propiciando la descomposición de un compuesto en especies más simples [@ref36].
La reacción global de la electrolisis del agua puede representarse como [@eqh2o]
La reacción global de la electrolisis del agua puede representarse como [@eq:h2o]
Mario Guillermo Ponce Hernández
1 week ago