Interferometric detection and control of cantilever displacement in NC-AFM applications

von Schmidsfeld, Alexander

11 July 2016

The interferometric cantilever displacement detection in non-contact atomic force microscopy (NC-AFM) is in fundamental aspects explored and optimized. Furthermore, the opto-mechanical interaction of the light field with the cantilever is investigated in detail. Cantilevers are harmonic oscillators that are designed to have a high sensitivity for the detection of minute external forces typically originating from tip-sample interaction. In this work, however, the high sensitivity is used for detailed studies of opto-mechanical forces due to the radiation pressure of the light interacting with the cantilever. The interferometer in the NC-AFM setup consists of an optical cavity working similar to a Fabry-Pérot interferometer in combination with a reference interference arm working similar to a Michelson interferometer combining multi-beam interference with a reference beam resulting in a complex superposition of beams forming the interferometric intensity modulation signal. The character of the interferometer can be adjusted from predominant Michelson to predominant Fabry-Pérot characteristics by the optical loss inside the cavity. A systematic approach for accurate alignment, by using 3D intensity maps and intensity-over-distance curves, as well as the implications of deficient fiber-cantilever configurations are explored and the impact of the interferometer configuration on the detection system noise floor is investigated. A new physical property, namely, the Fabry-Perot enhancement factor is introduced that is a direct measure for the light intensity interacting with the cantilever compared to the reference beam intensity reflected back inside the fiber. The quantification of the optical loss yields an exact knowledge of the amount of light interacting with the cantilever that is crucial to understand opto-mechanical effects. The resulting opto-mechanical force varies sinusoidally during the course of one oscillation cycle. It is a key result of this work that the sinusoidal modification of the cantilever restoring force can be described analogue to the restoring force of a pendulum. This results in an observable amplitude dependent frequency shift of the cantilever oscillation, allowing a calculation of the ratio of the opto-mechanical force relative to the cantilever restoring force and thus allows an in-situ measurement of the cantilever stiffness with remarkable precision. Further investigation of the cantilever oscillation yields that other characteristic properties of the oscillation are significantly modified by the opto-mechanical interaction. The observed effective fundamental mode Q-factor drops significantly while the cantilever amplitude response to a certain excitation voltage increases. A discrete numerical model describing the cantilever as a 1D linear chain of mass points is implemented, yielding that the additional opto-mechanical force results in a partial pinning of the cantilever at the edges of the interferometric fringes. Pinning efficiently shifts energy from the fundamental mode to higher modes and modes of a pinned cantilever, resulting in a complex modal structure.

NC-AFM

atomic force microscopy

interferometer

33.05 - Experimentalphysik

42.25.Hz - Interference

ddc:530

Characterization of acoustic and mechanical properties of common tropical woods used in classical guitars

Sproßmann, Robert, Zauer, Mario, Wagenführ, André

14 November 2017

There is a need of substitution woods for the use in musical instruments because of the limited availabil-ity of some commonly used tropical tonewoods. Before substitutions can be found, it is necessary to knowabout the required properties. Hence, in this paper acoustical, mechanical and physical properties of fourcommon tropical hardwoods (Indian rosewood, ziricote, African blackwood and ebony) were determinedbecause there are less literature values for some properties available, e.g. internal friction, hardness orswelling behaviour. The acoustic properties were determined by means of experimental modal analysis,the mechanical properties by means of static bending tests and tests of the Brinell hardness. For the swel-ling behaviour the volume swelling and also the differential swelling coefficients were determined. Withthe results it is possible to look for new ‘tonewoods’ or to specifically modified woods, e.g. thermally trea-ted wood, to substitute tropical wood species.

Klassische Gitarren

Akustische Eigenschaften

Mechanische Eigenschaften

Tropenhölzer

Modalanalyse

Technische Universität Dresden

Publikationsfonds

Classical guitars

Acoustic properties

Mechanical properties

Tropical woods

Modal analysis

Technische Universität Dresden

Publishing Funds

ddc:520

rvk:UA 1000

Characterization of acoustic and mechanical properties of common tropical woods used in classical guitars

Sproßmann, Robert, Zauer, Mario, Wagenführ, André

14 November 2017

There is a need of substitution woods for the use in musical instruments because of the limited availabil-ity of some commonly used tropical tonewoods. Before substitutions can be found, it is necessary to knowabout the required properties. Hence, in this paper acoustical, mechanical and physical properties of fourcommon tropical hardwoods (Indian rosewood, ziricote, African blackwood and ebony) were determinedbecause there are less literature values for some properties available, e.g. internal friction, hardness orswelling behaviour. The acoustic properties were determined by means of experimental modal analysis,the mechanical properties by means of static bending tests and tests of the Brinell hardness. For the swel-ling behaviour the volume swelling and also the differential swelling coefficients were determined. Withthe results it is possible to look for new ‘tonewoods’ or to specifically modified woods, e.g. thermally trea-ted wood, to substitute tropical wood species.

info:eu-repo/classification/ddc/520

ddc:520

Mechanische Eigenschaften kristallin-amorpher Schichtpakete / Mechanical properties of crystalline-amorphous multilayers

Knorr, Inga

13 December 2012

No description available.

530 Physik

Physik (PPN621336750)

Metalle {Physik} (PPN621341347)

Physics

Mechanische Eigenschaften

dünne Schichten

Schichtpakete

Nanokomposit

Festigkeit

Duktilität

Verformungsmechanismen

Nanoindentierung

Mikrodruckversuche

mechanical properties

thin films

multilayers

nanocomposite

strength

ductility

deformation mechanisms

nanoindentation

microcompression

33.00 Physik: Allgemeines

33.68 Oberflächen

Dünne Schichten

Grenzflächen

33.62 Mechanische Eigenschaften

akustische Eigenschaften

thermische Eigenschaften

33.66 Amorpher Zustand

Gläser