Single-molecule electronic detection using nanoscale field-effect devices

Author

Sorgenfrei, Sebastian ; Shepard, Kenneth

Author_Institution

Bioelectron. Syst. Lab., Columbia Univ., New York, NY, USA

fYear

2011

fDate

5-9 June 2011

Firstpage

712

Lastpage

717

Abstract

Traditionally, biomolecular systems have been studied in ensemble. While much can be determined with ensemble measurements, scientific and technological interest is rapidly moving to single-molecule techniques, which rely primarily on fluorescent markers and advanced microscopy techniques. In this paper, we describe recent work using nanoscale transistors based on carbon nanotubes as charge-sensitive detectors. We show carbon nanotubes can be used for ensemble studies through sidewall adsorption. Sensitivity can be greatly enhanced though an engineered defect in the nanotube. Biomolecular interactions are characterized by random-telegraph-noise response, which can be analyzed to study single-molecule kinetics and thermodynamics.

Keywords

adsorption; carbon nanotubes; field effect devices; fluorescence; macromolecules; molecular biophysics; transistors; biomolecular interactions; biomolecular systems; carbon nanotubes; ensemble measurements; fluorescent markers; microscopy techniques; nanoscale field-effect devices; nanoscale transistors; random-telegraph-noise response; sidewall adsorption; single-molecule electronic detection; CMOS integrated circuits; Carbon nanotubes; DNA; Logic gates; Noise; Sensitivity; Sensors; Single-molecule sensing; carbon nanotube transistors;

fLanguage

English

Publisher

ieee

Conference_Titel

Design Automation Conference (DAC), 2011 48th ACM/EDAC/IEEE

Conference_Location

New York, NY

ISSN

0738-100x

Print_ISBN

978-1-4503-0636-2

Type

conf

Filename

5981992