Simultaneous optical detection techniques, interferometry, and optical beam deflection for dynamic mode control of scanning force microscopy

Hoummady, M.; Farnault, E.; Yahiro, Takehisa; Kawakatsu, Hideki

doi:10.1116/1.589395

Cited by 13 publications

(7 citation statements)

References 7 publications

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“…In this paper, we will demonstrate the ability of higher modes to enhance sensitivity to force gradients. For our experiments, we used a home-made force microscope with an original detection technique based on a two degrees of freedom optical detection system: interferometry and optical beam deflection [7], and a silicon cantilever driven at higher modes from the first to the fourth flexural mode (up to 6 MHz). By recording the quasi-instantaneous frequency response at different tipsample distances, the two main long-range interactions were distinguished, i.e.…”

Section: Introductionmentioning

confidence: 99%

“…This simultaneous optical detection [13] is very suitable for characterizing the cantilever vibration within two degrees of free- dom. It becomes a powerful tool when the beam is driven at high flexural mode owing to the appearance of nodes and antinodes [7]. For a given tip-sample distance, the frequency response of the cantilever is recorded using a network analyzer (Hewlett Packard 8752C).…”

Section: Introductionmentioning

confidence: 99%

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Enhanced sensitivity to force gradients by using higher flexural modes of the atomic force microscope cantilever

Hoummady

Farnault

1998

Applied Physics A: Materials Science & Processing

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Higher flexural modes of a Si cantilever are used in order to increase the operating frequencies in non-contact mode scanning force microscopy. By recording frequency responses at different tip-sample distances and by using different flexural modes, long-range tip-sample interactions are studied. The experimental results reveal that operating at higher resonant modes makes it possible to improve sensitivity to force gradients and to avoid overlap between hydrodynamic interactions and attractive interactions in the range of 100-nm tip-sample distances. Using the second-harmonic, a sevenfold-enhanced sensitivity is demonstrated. Finally, discussion on the appropriate technique related to force gradient measurement, i.e. slope detection or frequency modulation technique, is reported.During the last decade, atomic force microscopy (AFM) [1] has atttacted a great interest in a wide field of applications including biological living cells [2]. For this kind of application, dynamic mode is the most used operating mode and avoids damage to such samples. There are numerous advantages in developing an AFM operating at high frequencies.Mainly, it allows fast scanning and reduces the thermal noise, and therefore the ultimate sensitivity to force gradients. Imaging systems with true atomic resolution as well as high-speed data storage are the main driving forces in this field. In order to obtain very high operating frequencies, fabrication of nanometric-scale cantilevers of small mass has been already reported [3,4]. Due to the small size of the cantilever (typically sub-micron size), it requires more complicated detection systems. However, another alternative is to use conventional micromachined AFM cantilevers vibrating at higher flexural modes. Several groups are investigating this possibility. Rabe et al.[5] published a detailed analysis of cantilever vibration mechanisms, detecting more than 10 modes using silicon cantilevers. Recently, tapping mode images were performed by * Permanent address:Minne et al.[6] using higher flexural modes. The piezoresistive cantilever that was used was driven at 132 kHz, which corresponded to the second flexural mode of the clamped-free beam.A quantitative analysis of sensitivity enhancement using higher modes has not yet been achieved. In this paper, we will demonstrate the ability of higher modes to enhance sensitivity to force gradients. For our experiments, we used a home-made force microscope with an original detection technique based on a two degrees of freedom optical detection system: interferometry and optical beam deflection [7], and a silicon cantilever driven at higher modes from the first to the fourth flexural mode (up to 6 MHz). By recording the quasi-instantaneous frequency response at different tipsample distances, the two main long-range interactions were distinguished, i.e. air damping and attractive forces. The results reveal that higher order flexural modes allow us to avoid overlap between these two interactions.For measurement of force gradients, two techniques have ...

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Enhanced sensitivity to force gradients by using higher flexural modes of the atomic force microscope cantilever

Hoummady

Farnault

1998

Applied Physics A: Materials Science & Processing

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“…The latter technique is subject to interference fringes that are formed between the planar metal disk (b300 nm diameter with a central dielectric) and the surface. 19 Furthermore, various shadowing effects have to be considered both in reflection (light collected through a 20-100 nm narrow slice of air with radius of ca. 150 nm) and transmission (stray centers in the far-field).…”

Section: Artifacts In Snom On Rough Surfacesmentioning

confidence: 99%

Artifacts in scanning near-field optical microscopy (SNOM) due to deficient tips

Kaupp

Herrmann

Haak

1999

J. Phys. Org. Chem.

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Apertureless scanning near-field optical microscopy (SNOM) in the reflection-back-to-the-fiber configuration is possible on rough surfaces of practical importance and reaches 15 nm lateral resolution. The feedback for constant distance mode is provided by shear-force atomic force microscopy. Any artifacts in the atomic force microscopy will translate into artificial optical responses. Very sharp tapered tips (radius ca. 15 nm, apex angle`10°) are required. Only these give the strongly enhanced reflectance in shear-force distance, do not break as easily as do more blunt tips, and can follow the topography in order to provide chemical SNOM contrast without topographic errors. In the absence of significant reflectance enhancement, if blunt or abrased or broken tips are used, not SNOM but artificial 'optical contrast' is recorded. Metal-coated tips are unsuitable: they become hot, give poor resolution and are the source of numerous additional artifacts that are summarized for comparison. The SNOM artifacts are subdivided into:* topographic errors-if chemical uniform topography does give some optical response; * lack of spatial correlation-if the optical signal does not reproduce the site of the emitter or of the chemical contrast; * tip imaging-very large features and more or less negative differentials therefrom; * contrast inversion-false sign of optical contrast; * split optical contrast-signal is split into two unequal parts with the same (false) sign of the contrast; * artificial stripes-instead of chemical/emissive contrast artificial stripes, that are not always 'interference fringes' or 'edge-contrast'.The artifacts can be easily recognized in published images from different techniques and modes of SNOM. Their analysis would be facilitated if full x/y/z data were published instead of two-dimensional images. We therefore disclose interactively analyzable VRML data in the EPOC version.

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“…Alternative interferometric techniques, such as other variants of homodyne interferometry [26–28], heterodyne interferometry [29] and low-cost feedback interferometry [30], may also be employed to measure the collective micro-asperity deformation. Non-interferometric optical methods, such as the laser-beam deflection technique [31], which is also employed in atomic force microscopy to measure the deflections of the cantilever, can be used as well. Compared to the above-mentioned interferometric alternatives, HQLI has a simple electronic and optical construction, where all of the components can be easily available on market for a reasonable price.…”

Section: Introductionmentioning

confidence: 99%

A Homodyne Quadrature Laser Interferometer for Micro-Asperity Deformation Analysis

Pogačnik

Požar

Kalin

et al. 2013

Sensors

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We report on the successful realization of a contactless, non-perturbing, displacement-measuring system for characterizing the surface roughness of polymer materials used in tribological applications. A single, time-dependent, scalar value, dubbed the collective micro-asperity deformation, is extracted from the normal-displacement measurements of normally loaded polymer samples. The displacement measurements with a sub-nanometer resolution are obtained with a homodyne quadrature laser interferometer. The measured collective micro-asperity deformation is critical for a determination of the real contact area and thus for the realistic contact conditions in tribological applications. The designed measuring system senses both the bulk creep as well as the micro-asperity creep occurring at the roughness peaks. The final results of our experimental measurements are three time-dependent values of the collective micro-asperity deformation for the three selected surface roughnesses. These values can be directly compared to theoretical deformation curves, which can be derived using existing real-contact-area models.

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Simultaneous optical detection techniques, interferometry, and optical beam deflection for dynamic mode control of scanning force microscopy

Cited by 13 publications

References 7 publications

Enhanced sensitivity to force gradients by using higher flexural modes of the atomic force microscope cantilever

Enhanced sensitivity to force gradients by using higher flexural modes of the atomic force microscope cantilever

Artifacts in scanning near-field optical microscopy (SNOM) due to deficient tips

A Homodyne Quadrature Laser Interferometer for Micro-Asperity Deformation Analysis

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