Your search keyword '"R. B. Karabalin"' showing total 5 results

1. Nonlinear Mode-Coupling in Nanomechanical Systems

Author

R. B. Karabalin, John E. Sader, Michael L. Roukes, Luis Guillermo Villanueva, and Matthew H. Matheny

Subjects

Transducers, Bioengineering, Nanotechnology, Transduction (psychology), Article, sensor, Electronic engineering, euler-bernoulli beam, General Materials Science, Mechanical Phenomena, Physics, Nanoelectromechanical systems, piezoresistive sensors, Mechanical Engineering, piezoelectric actuators, resolution, silicon, Ranging, General Chemistry, mass-spectrometry, Condensed Matter Physics, Characterization (materials science), Nonlinear system, Transducer, Nonlinear Dynamics, Mode coupling, nanomechanical systems, coupled mode analysis, Beam (structure)

Abstract

Understanding and controlling nonlinear coupling between vibrational modes is critical for the development of advanced nanomechanical devices; it has important implications for applications ranging from quantitative sensing to fundamental research. However, achieving accurate experimental characterization of nonlinearities in nanomechanical systems (NEMS) is problematic. Currently employed detection and actuation schemes themselves tend to be highly nonlinear, and this unrelated nonlinear response has been inadvertently convolved into many previous measurements. In this Letter we describe an experimental protocol and a highly linear transduction scheme, specifically designed for NEMS, that enables accurate, in situ characterization of device nonlinearities. By comparing predictions from Euler-Bernoulli theory for the intra- and intermodal nonlinearities of a doubly clamped beam, we assess the validity of our approach and find excellent agreement.

Published

2013

2. Parametric Nanomechanical Amplification at Very High Frequency

Author

X. L. Feng, Michael L. Roukes, and R. B. Karabalin

Subjects

Materials science, Surface Properties, Bioengineering, Resonator, Optics, Quality (physics), Materials Testing, Nanotechnology, General Materials Science, Particle Size, Parametric statistics, Nanoelectromechanical systems, business.industry, Mechanical Engineering, Amplifier, Temperature, Membranes, Artificial, General Chemistry, Models, Theoretical, Condensed Matter::Mesoscopic Systems and Quantum Hall Effect, Condensed Matter Physics, Nanostructures, Optoelectronics, Parametric oscillator, business, Joule heating, Beam (structure)

Abstract

Parametric resonance and amplification are important in both fundamental physics and technological applications. Here we report very high frequency (VHF) parametric resonators and mechanical-domain amplifiers based on nanoelectromechanical systems (NEMS). Compound mechanical nanostructures patterned by multilayer, top-down nanofabrication are read out by a novel scheme that parametrically modulates longitudinal stress in doubly clamped beam NEMS resonators. Parametric pumping and signal amplification are demonstrated for VHF resonators up to approximately 130 MHz and provide useful enhancement of both resonance signal amplitude and quality factor. We find that Joule heating and reduced thermal conductance in these nanostructures ultimately impose an upper limit to device performance. We develop a theoretical model to account for both the parametric response and nonequilibrium thermal transport in these composite nanostructures. The results closely conform to our experimental observations, elucidate the frequency and threshold-voltage scaling in parametric VHF NEMS resonators and sensors, and establish the ultimate sensitivity limits of this approach.

Published

2009

3. A nanoscale parametric feedback oscillator

Author

Michael L. Roukes, Eyal Kenig, L. Guillermo Villanueva, R. B. Karabalin, Matthew H. Matheny, and Michael Cross

Subjects

Computer science, FOS: Physical sciences, Bioengineering, Topology (electrical circuits), Noise (electronics), Feedback, Reduction (complexity), Resonator, Oscillometry, Mesoscale and Nanoscale Physics (cond-mat.mes-hall), Electronic engineering, Nanotechnology, General Materials Science, Nanoscopic scale, Parametric statistics, Nanoelectromechanical systems, Condensed Matter - Mesoscale and Nanoscale Physics, Mechanical Engineering, General Chemistry, Equipment Design, Micro-Electrical-Mechanical Systems, Condensed Matter Physics, Equipment Failure Analysis, Nonlinear system, Physics - Optics, Optics (physics.optics)

Abstract

We describe and demonstrate a new oscillator topology, the parametric feedback oscillator (PFO). The PFO paradigm is applicable to a wide variety of nanoscale devices, and opens the possibility of new classes of oscillators employing innovative frequency-determining elements, like such as nanoelectromechanical systems (NEMS), facilitating integration with circuitry, and reduction in cost and system size reduction. We show that the PFO topology can also improve nanoscale oscillator performance by circumventing detrimental effects that are otherwise imposed by the strong device nonlinearity in this size regime., Comment: 17 pages, 3 figures

Published

2011

4. Wiring nanoscale biosensors with piezoelectric nanomechanical resonators

Author

Michael L. Roukes, Jiangang Du, R. B. Karabalin, Christof Koch, Sotiris C. Masmanidis, and Akram Sarwat Sadek

Subjects

Materials science, Conductometry, Transducers, Bioengineering, Nanotechnology, Integrated circuit, Biosensing Techniques, Vibration, law.invention, Resonator, law, Hardware_INTEGRATEDCIRCUITS, General Materials Science, Interconnection, Nanoelectromechanical systems, Mechanical Engineering, General Chemistry, Equipment Design, Micro-Electrical-Mechanical Systems, Condensed Matter Physics, Piezoelectricity, Line (electrical engineering), Equipment Failure Analysis, Microelectrode, Computer-Aided Design, Biosensor

Abstract

Nanoscale integrated circuits and sensors will require methods for unobtrusive interconnection with the macroscopic world to fully realize their potential. We report on a nanoelectromechanical system that may present a solution to the wiring problem by enabling information from multisite sensors to be multiplexed onto a single output line. The basis for this method is a mechanical Fourier transform mediated by piezoelectrically coupled nanoscale resonators. Our technique allows sensitive, linear, and real-time measurement of electrical potentials from conceivably any voltage-sensitive device. With this method, we demonstrate the direct transduction of neuronal action potentials from an extracellular microelectrode. This approach to wiring nanoscale devices could lead to minimally invasive implantable sensors with thousands of channels for in vivo neuronal recording, medical diagnostics, and electrochemical sensing.

Published

2010

5. Parametric Nanomechanical Amplification at Very High Frequency.

Author

R. B. Karabalin, X. L. Feng, and M. L. Roukes

Subjects

*NANOELECTROMECHANICAL systems, *RESONATORS, *NANOSTRUCTURES, *QUALITY factor meters, *THERMAL conductivity

Abstract

Parametric resonance and amplification are important in both fundamental physics and technological applications. Here we report very high frequency (VHF) parametric resonators and mechanical-domain amplifiers based on nanoelectromechanical systems (NEMS). Compound mechanical nanostructures patterned by multilayer, top-down nanofabrication are read out by a novel scheme that parametrically modulates longitudinal stress in doubly clamped beam NEMS resonators. Parametric pumping and signal amplification are demonstrated for VHF resonators up to ∼130 MHz and provide useful enhancement of both resonance signal amplitude and quality factor. We find that Joule heating and reduced thermal conductance in these nanostructures ultimately impose an upper limit to device performance. We develop a theoretical model to account for both the parametric response and nonequilibrium thermal transport in these composite nanostructures. The results closely conform to our experimental observations, elucidate the frequency and threshold-voltage scaling in parametric VHF NEMS resonators and sensors, and establish the ultimate sensitivity limits of this approach. [ABSTRACT FROM AUTHOR]

Published

2009