Simulation of a model nanopore sensor: Ion competition underlies device behavior

Abstract: We study a model nanopore sensor with which a very low concentration of analyte molecules can be detected on the basis of the selective binding of the analyte molecules to the binding sites on the pore wall. The bound analyte ions partially replace the current-carrier cations in a thermodynamic competition. This competition depends both on the properties of the nanopore and the concentrations of the competing ions (through their chemical potentials). The output signal given by the device is the current reducti… Show more

“…The bulk value is experimental (D bulk K + = 1.849 × 10 −9 m 2 s −1 and D bulk Cl − = D bulk X = 2.032 × 10 −9 m 2 s −1 ), while D pore i just scales the current without influencing the I/I 0 ratio. Following our previous studies [45,8,46,47] here we set the relation D…”

“…1). Each ring contains 4 binding sites [8]. The binding potential between a site and an analyte ion is the square-well (SW) potential:…”

“…The SW potential acts only on the X ions in the simulations. An analysis on the effect of the ε SW and d SW parameters has been given in our previous work [8].…”

“…This case was already studied in our first paper on the subject [8] considering a symmetric sensor. The device function is the current in the presence of the X ions (I) in relation to the current in the absence of the X ions (I 0 ).…”

“…We apply the Nernst-Planck (NP) transport equation and couple it to LEMC resulting in a hybrid method, called NP+LEMC. This method was successfully applied for various problems in the last couple of years such as particle transport through model membranes [39,40], ion channels [41,42,43], and nanopores [44,45,8,46,47,1,48].…”

Application of a bipolar nanopore as a sensor: rectification as an additional device function

“…The bulk value is experimental (D bulk K + = 1.849 × 10 −9 m 2 s −1 and D bulk Cl − = D bulk X = 2.032 × 10 −9 m 2 s −1 ), while D pore i just scales the current without influencing the I/I 0 ratio. Following our previous studies [45,8,46,47] here we set the relation D…”

“…1). Each ring contains 4 binding sites [8]. The binding potential between a site and an analyte ion is the square-well (SW) potential:…”

“…The SW potential acts only on the X ions in the simulations. An analysis on the effect of the ε SW and d SW parameters has been given in our previous work [8].…”

“…This case was already studied in our first paper on the subject [8] considering a symmetric sensor. The device function is the current in the presence of the X ions (I) in relation to the current in the absence of the X ions (I 0 ).…”

“…We apply the Nernst-Planck (NP) transport equation and couple it to LEMC resulting in a hybrid method, called NP+LEMC. This method was successfully applied for various problems in the last couple of years such as particle transport through model membranes [39,40], ion channels [41,42,43], and nanopores [44,45,8,46,47,1,48].…”

Application of a bipolar nanopore as a sensor: rectification as an additional device function

Influence of location junction on ion transfer behavior in conical nanopores with bipolar polyelectrolyte brushes

The effect of the charge pattern on the applicability of a nanopore as a sensor