NANOCHANNEL-BASED SENSOR SYSTEM FOR USE IN DETECTING CHEMICAL OR BIOLOGICAL SPECIES
First Claim
1. A sensor system for detecting a chemical or biological species in an analyte, comprising:
- a sensing element including one or more nanochannels, each nanochannel having a minimum of two ends and having an outer surface functionalized to chemically interact with the species to create a corresponding surface potential on the outer surface of the nanochannel, each nanochannel having a geometric shape of sufficiently small cross section to exhibit a shift of a differential conductance characteristic into a negative bias operating region by a shift amount being dependent on the surface potential; and
a bias and measurement circuit system operative (1) to apply a bias voltage across two ends of the nanochannels, the bias voltage being sufficiently negative to achieve a desired dependence of the differential conductance of the sensing element on the surface potential of the nanochannels, the desired dependence having a steeply sloped region of high amplification substantially greater than a reference amplification exhibited by the sensing element at a zero-bias condition, and (2) to measure the differential conductance of the sensing element and to convert the measured differential conductance into a signal indicative of presence or activity of the species;
wherein an electrically parallel array of three-dimensionally structured nanochannels increase the surface to volume ratio and thereby the sensitivity of the nanochannels, and wherein side and top gates allow programmable control of the surface potential and programmable control of the surface functionalization.
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Abstract
A sensor system for detecting a chemical or biological species includes a sensing element and a bias and measurement circuit. The sensing element includes nanochannels having an outer surface functionalized for interaction with the species to create a surface potential, and each having a sufficiently small cross section to exhibit a shift of differential conductance into a negative bias operating region by a shift amount dependent on the surface potential. The bias and measurement circuit applies a bias voltage across two ends of the nanochannels sufficiently negative to achieve a desired dependence of the differential conductance on the surface potential. The dependence has a steeply sloped region of high amplification substantially greater than a reference amplification at a zero-bias condition, thus achieving relatively high signal-to-noise ratio. The bias and measurement circuit converts the measured differential conductance into a signal indicative of presence or activity of the species.
9 Citations
20 Claims
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1. A sensor system for detecting a chemical or biological species in an analyte, comprising:
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a sensing element including one or more nanochannels, each nanochannel having a minimum of two ends and having an outer surface functionalized to chemically interact with the species to create a corresponding surface potential on the outer surface of the nanochannel, each nanochannel having a geometric shape of sufficiently small cross section to exhibit a shift of a differential conductance characteristic into a negative bias operating region by a shift amount being dependent on the surface potential; and a bias and measurement circuit system operative (1) to apply a bias voltage across two ends of the nanochannels, the bias voltage being sufficiently negative to achieve a desired dependence of the differential conductance of the sensing element on the surface potential of the nanochannels, the desired dependence having a steeply sloped region of high amplification substantially greater than a reference amplification exhibited by the sensing element at a zero-bias condition, and (2) to measure the differential conductance of the sensing element and to convert the measured differential conductance into a signal indicative of presence or activity of the species; wherein an electrically parallel array of three-dimensionally structured nanochannels increase the surface to volume ratio and thereby the sensitivity of the nanochannels, and wherein side and top gates allow programmable control of the surface potential and programmable control of the surface functionalization. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10)
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11. A method of detecting a chemical or biological species in an analyte, comprising:
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exposing a sensing element to the analyte, the sensing element including one or more elongated system nanochannels, each nanochannel having first and second ends and having an outer surface functionalized to chemically interact with the species to create a corresponding surface potential on the outer surface of the nanochannel, each nanochannel having a sufficiently small cross section to exhibit a shift of a differential conductance characteristic into a negative bias operating region by a shift amount being dependent on the surface potential; applying a bias voltage across the first and second ends of the nanochannels, the bias voltage being sufficiently negative to achieve a desired dependence of the differential conductance of the sensing element on the surface potential of the nanochannels, the desired dependence having a steeply sloped region of high amplification substantially greater than a reference amplification exhibited by the sensing element at a zero-bias condition; and measuring the differential conductance of the sensing element and converting the measured differential conductance into a signal indicative of presence or activity of the species. - View Dependent Claims (12, 13, 14, 15, 16, 17, 18, 19, 20)
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Specification