Micromachined piezoresistive single crystal silicon cantilever sensors

Su, Yi

January 1997

No description available.

629.892

Atomic force microscope

Force Transduction and Strain Dynamics through Actin Stress Fibres of the Cytoskeleton

Guolla, Louise

29 September 2011

It is becoming clear that mechanical stimuli are critical in regulating cell biology; however, the short-term structural response of a cell to mechanical forces remains relatively poorly understood. We mechanically stimulated cells expressing actin-EGFP with controlled forces (0-20nN) in order to investigate the cell’s structural response. Two clear force dependent responses were observed: a short-term local deformation of actin stress fibres and a long-term force-induced remodelling of stress fibres at cell edges, far from the point of contact. We were also able to quantify strain dynamics occurring along stress fibres. The cell exhibits complex heterogeneous negative and positive strain fluctuations along stress fibres, indicating localized dynamic contraction and expansion. A ~50% increase in myosin contractile activity is apparent following application of 20nN force. Directly visualizing force-propagation and stress fibre strain dynamics has revealed new information about the pathways involved in mechanotransduction which ultimately govern the downstream response of a cell.

Atomic Force Microscope

Actin

Cytoskeleton

Mechanotransduction

Biophysics

Force Transduction and Strain Dynamics through Actin Stress Fibres of the Cytoskeleton

Guolla, Louise

29 September 2011

It is becoming clear that mechanical stimuli are critical in regulating cell biology; however, the short-term structural response of a cell to mechanical forces remains relatively poorly understood. We mechanically stimulated cells expressing actin-EGFP with controlled forces (0-20nN) in order to investigate the cell’s structural response. Two clear force dependent responses were observed: a short-term local deformation of actin stress fibres and a long-term force-induced remodelling of stress fibres at cell edges, far from the point of contact. We were also able to quantify strain dynamics occurring along stress fibres. The cell exhibits complex heterogeneous negative and positive strain fluctuations along stress fibres, indicating localized dynamic contraction and expansion. A ~50% increase in myosin contractile activity is apparent following application of 20nN force. Directly visualizing force-propagation and stress fibre strain dynamics has revealed new information about the pathways involved in mechanotransduction which ultimately govern the downstream response of a cell.

Atomic Force Microscope

Actin

Cytoskeleton

Mechanotransduction

Biophysics

STIFFNESS CALIBRATION OF ATOMIC FORCE MICROSCOPY PROBES UNDER HEAVY FLUID LOADING

Kennedy, Scott Joseph

January 2010

<p>This research presents new calibration techniques for the characterization of atomic force microscopy cantilevers. Atomic force microscopy cantilevers are sensors that detect forces on the order of pico- to nanonewtons and displacements on the order of nano- to micrometers. Several calibration techniques exist with a variety of strengths and weaknesses. This research presents techniques that enable the noncontact calibration of the output sensor voltage-to-displacement sensitivity and the cantilever stiffness through the analysis of the unscaled thermal vibration of a cantilever in a liquid environment.</p><p>A noncontact stiffness calibration method is presented that identifies cantilever characteristics by fitting a dynamic model of the cantilever reaction to a thermal bath according to the fluctuation-dissipation theorem. The fitting algorithm incorporates an assumption of heavy fluid loading, which is present in liquid environments.</p><p>The use of the Lorentzian line function and a variable-slope noise model as an alternate approach to the thermal noise method was found to reduce the difference between calibrations preformed on the same cantilever in air and in water relative to existing techniques. This alternate approach was used in combination with the new stiffness calibration technique to determine the voltage-to-displacement sensitivity without requiring contact loading of the cantilever.</p><p>Additionally, computational techniques are presented in the investigation of alternate cantilever geometries, including V-shaped cantilevers and warped cantilevers. These techniques offer opportunities for future research to further reduce the uncertainty of atomic force microscopy calibration.</p> / Dissertation

Mechanical Engineering

Atomic force microscope

calibration

Scanning Probe Alloying Nanolithography (SPAN)

Lee, Hyungoo

2009 May 1900

In recent years, nanowires have become increasingly important due to their unique properties and applications. Thus, processes in the fabrication to nanostructures has come a focal point in research. In this research, a new method to fabricate nanowires has been developed. The new technique is called the Scanning Probe Alloying Nanolithography (SPAN). The SPAN was processed using an Atomic Force Microscope (AFM) in ambient environment. Firstly, an AFM probe was coated with gold (Au), and then slid on a silicon (Si) substrate. The contact-sliding motion generated a nanostructure on the substrate, instead of wear. Subsequently, careful examination was carried out at the scale relevant to an AFM probe, in terms of physical dimension and electrical conductivity. The measured conductivity value of the generated microstructures was found to be between the conductivity values of pure silicon and gold. Simple analysis indicated that the microstructures were formed due to frictional energy dispersed in the interface forming a bond to sustain mechanical wear. This research proves the feasibilities of tip-based nanomanufacturing. The SPAN process was developed to increase efficiency of the technique. This study also explored the possibility of the applications as a biosensor and a flexible device. This dissertation contains nine sections. The first section introduces backgrounds necessary to understand the subject matter. It reviews current status of the nanofabrication technologies. The basic concepts of AFM are also provided. The second section discusses the motivation and goals in detail. The third section covers the new technology, scanning probe alloying nanolithography (SPAN) to fabricate nanostructures. The fourth talks about characterization of nanostructures. Subsequently, the characterized nanostructures and their mechanical, chemical, and electrical properties are discussed in the fifth section. In the sixth section, the new process to form a nanostructure is evaluated and its mechanism is discussed. The seventh section discusses the feasibility of the nanostructures to be used in biosensors and flexible devices. The conclusion of the research is summarized in the seventh section.

Force Transduction and Strain Dynamics through Actin Stress Fibres of the Cytoskeleton

Guolla, Louise

29 September 2011

It is becoming clear that mechanical stimuli are critical in regulating cell biology; however, the short-term structural response of a cell to mechanical forces remains relatively poorly understood. We mechanically stimulated cells expressing actin-EGFP with controlled forces (0-20nN) in order to investigate the cell’s structural response. Two clear force dependent responses were observed: a short-term local deformation of actin stress fibres and a long-term force-induced remodelling of stress fibres at cell edges, far from the point of contact. We were also able to quantify strain dynamics occurring along stress fibres. The cell exhibits complex heterogeneous negative and positive strain fluctuations along stress fibres, indicating localized dynamic contraction and expansion. A ~50% increase in myosin contractile activity is apparent following application of 20nN force. Directly visualizing force-propagation and stress fibre strain dynamics has revealed new information about the pathways involved in mechanotransduction which ultimately govern the downstream response of a cell.

Atomic Force Microscope

Actin

Cytoskeleton

Mechanotransduction

Biophysics

Force Transduction and Strain Dynamics through Actin Stress Fibres of the Cytoskeleton

Guolla, Louise

January 2011

It is becoming clear that mechanical stimuli are critical in regulating cell biology; however, the short-term structural response of a cell to mechanical forces remains relatively poorly understood. We mechanically stimulated cells expressing actin-EGFP with controlled forces (0-20nN) in order to investigate the cell’s structural response. Two clear force dependent responses were observed: a short-term local deformation of actin stress fibres and a long-term force-induced remodelling of stress fibres at cell edges, far from the point of contact. We were also able to quantify strain dynamics occurring along stress fibres. The cell exhibits complex heterogeneous negative and positive strain fluctuations along stress fibres, indicating localized dynamic contraction and expansion. A ~50% increase in myosin contractile activity is apparent following application of 20nN force. Directly visualizing force-propagation and stress fibre strain dynamics has revealed new information about the pathways involved in mechanotransduction which ultimately govern the downstream response of a cell.

Atomic Force Microscope

Actin

Cytoskeleton

Mechanotransduction

Biophysics

The Stochastic Dynamics of an Array of Micron Scale Cantilevers in Viscous Fluid

Clark, Matthew Taylor

26 September 2006

The stochastic dynamics of an array of closely spaced micron scale cantilevers in a viscous fluid is considered. The stochastic cantilever dynamics are due to the constant buffeting of fluid particles by Brownian motion and the dynamics of adjacent cantilevers are correlated due to long range effects of fluid dynamics. The measurement sensitivity of an experimental setup is limited by the magnitude of inherent stochastic motion. However, the magnitude of this noise can be decreased using correlated measurements allowing for improved force resolution. A correlated scheme is proposed using two atomic force microscope cantilevers for the purpose of analyzing the dynamics of single molecules in real time, a regime that is difficult to observe using current technologies. Using a recently proposed thermodynamic approach the hydrodynamic coupling of an array of cantilevers is quantified for precise experimental conditions through deterministic numerical simulations. Results are presented for an array of two readily available micron-scale cantilevers yielding the possible force sensitivity and time resolution of correlated measurements. This measurement scheme is capable of achieving a force resolution that is more than three fold more sensitive than that of a single cantilever when the two cantilevers are separated by 200 nm, with a time scale on the order of tens of microseconds. / Master of Science

correlated

fluid coupling

stochastic

atomic force microscope

Nanodeposition and plasmonically enhanced Raman spectroscopy on individual carbon nanotubes

Strain, Kirsten Margaret

January 2014

Single-walled carbon nanotubes (SWNTs) exhibit extraordinary properties: mechanical, thermal, optical and, possibly the most interesting, electrical. These all-carbon cylindrical structures can be metallic or semi-conducting depending on their precise structure. They have the potential to allow faster transistor switching speeds and smaller, more closely-packed interconnects in microelectronics. However, such applications are hindered by the difficulties of positioning the correct type of SWNT in a spatially precise location and orientation. In addition, greater understanding of the fundamental limits of SWNTs, such as the limit of current density, is needed for optimum operation in applications. The primary aim of this project was to increase the understanding of current density limitation by using in situ plasmonically enhanced Raman spectroscopy during electrical transport. The use of plasmonic metal nanostructures to enhance the Raman scattering should allow the acquisition of informative spectra from SWNTs away from their intrinsic resonance conditions. To achieve this aim, SWNTs must be integrated with plasmonic metal structures as well as electrical connections. This thesis presents two approaches for the integration of SWNTs with other nanometre-scaled features, in particular plasmonic nanoparticles. Fountain pen nanolithography uses a hollow nanopipette in place of the probe tip in an atomic force microscope (AFM), through which material can be delivered to a spatially precise position on a surface. Aqueous SWNT dispersion was delivered to chemically-functionalised silicon in this way, through pulled quartz pipettes with aperture diameters of 50 nm, 100 nm and 150 nm. The heights, widths and continuity of lines drawn on the surface by the nanopipette depended on the size, setpoint and lateral speed of the tip. A small bias voltage applied between the SWNT dispersion inside the pipette and the substrate allowed the deposition to be switched on or off depending on the polarity of the voltage, through the action of electroosmotic effects within the quartz capillary. The quality and density of the SWNT dispersion was found to be important for successful deposition to occur, since too low a concentration results in the lines deposited from the pipette being only surfactant but too high a concentration of bundles would quickly block the small tip of the pipette. Polarised Raman spectroscopy on SWNT deposited by fountain pen nanolithography showed that they had a high level of alignment parallel to the direction in which the pipette moved. Spherical gold nanoparticles with plasmonic properties suitable for enhancing Raman scattering were dropped onto samples containing individual SWNTs supported on a Si/SiO2 surface. Nanomanipulation with an atomic force microscope was used to push the gold nanoparticles onto the SWNTs. Raman spectra measured with and without the gold particles showed that the gold nanoparticles gave local enhancement factors of 24 for a single 150 nm nanoshell and 130 for a small cluster of 150 nm nanoshells. Polarised Raman studies on the cluster showed that the angle dependence deviated significantly from that expected of a bare SWNT. Electrical transport experiments with in situ plasmonically enhanced Raman spectroscopy may be performed on samples prepared from the methods described here. Such experiments would increase understanding of the electrical properties of SWNTs and how they relate to the vibrational and optical properties.

543

High Speed Atomic Force Microscope Design Using DVD Optics

Carlson, Thomas

13 May 2014

We examine the design of a high speed atomic force microscope using an optical pickup from a commercially available compact disc/digital versatile disc drive. An investigation of the commercial optical pickup is done with the goal of determining how it can be used for dimensional measurements on nanometer scale. An evaluation of noise sources, imaging capabilities, and functionality is performed.

High Speed Atomic Force Microscope

Physical Sciences and Mathematics

Physics