论文信息 - Low-noise dual-channel current amplifier for DNA sensing with solid-state nanopores

Low-noise dual-channel current amplifier for DNA sensing with solid-state nanopores

A compact platform for nanopore-based detection is presented. The system is tailored for high-capacitance (hundreds of pF) solid-state nanopores with integrated tunneling electrodes for DNA detection and label-free sequencing. This platform includes two low-noise current sensing channels and auxiliary biasing and selectable filtering circuits. In order to overcome the noise/bandwidth trade-off of the standard transimpedance configuration, an improved integrator-differentiator topology is adopted. The use of a discrete couple of matched JFETs at the differential input allows achieving very low equivalent input voltage noise (1.5nV/√Hz) critical with high input capacitance. Thus, the transimpedance amplifiers provide 100MO gain, 75kHz bandwidth and 11pArms noise, comparable with the state-of-the-art performance. The system design, its characterization and λ-DNA detection with a sub-20nm pore are reported.

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