论文信息 - Manipulation and controlled amplification of Brownian motion of microcantilever sensors

Manipulation and controlled amplification of Brownian motion of microcantilever sensors

Microcantilevers, such as those used in atomic force microscopy, undergo Brownian motion due to mechanical thermal noise. The root mean square amplitude of the Brownian motion of a cantilever typically ranges from 0.01–0.1 nm, which limits its use in practical applications. Here we describe a technique by which the Brownian amplitude and the Q factor in air and water can be amplified by three and two orders of magnitude, respectively. This technique is similar to a positive feedback oscillator, wherein the Brownian motion of the vibrating cantilever controls the frequency output of the oscillator. This technique can be exploited to improve sensitivity of microcantilever-based chemical and biological sensors, especially for sensors in liquid environments.

T. Thundat | A. Mehta | S. Cherian | D. Hedden

[1] Jiri Janata,et al. Principles of Chemical Sensors , 1989 .

[2] D. Rugar,et al. Frequency modulation detection using high‐Q cantilevers for enhanced force microscope sensitivity , 1991 .

[3] T. Gabrielson. Mechanical-thermal noise in micromachined acoustic and vibration sensors , 1993 .

[4] E. A. Wachter,et al. Detection of mercury vapor using resonating microcantilevers , 1995 .

[5] Thomas Thundat,et al. Adsorption-induced surface stress and its effects on resonance frequency of microcantilevers , 1995 .

[6] Thomas Thundat,et al. Viscous drag measurements utilizing microfabricated cantilevers , 1996 .

[7] Urs Dürig,et al. DYNAMIC FORCE MICROSCOPY BY MEANS OF THE PHASE-CONTROLLED OSCILLATOR METHOD , 1997 .

[8] J. Vig,et al. Noise in microelectromechanical system resonators , 1999, IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control.

[9] Javier Tamayo,et al. Piconewton regime dynamic force microscopy in liquid , 2000 .

[10] Todd Sulchek,et al. High-speed tapping mode imaging with active Q control for atomic force microscopy , 2000 .