Theories of scanning probe microscopes at the atomic scale

Hofer, Werner A.; Foster, Adam S.; Shluger, Alexander L.

doi:10.1103/revmodphys.75.1287

Cited by 447 publications

(466 citation statements)

References 225 publications

(212 reference statements)

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“…Dynamic SFM measures the change in frequency (detuning f ) of an oscillating cantilever due to the interaction of a tip at the end of the cantilever with the surface [5][6][7]. Before taking measurements, the fast scanning direction was changed during scanning in the constant f mode by an adjustment of the scanning angle until the fast scanning direction was parallel to the surface with an error of a few degrees.…”

Section: Samples and Instrumentsmentioning

confidence: 99%

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Imaging nanoclusters in theconstant height modeof the dynamic SFM

et al. 2006

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For the first time, high quality images of metal nanoclusters which were recorded in the constant height mode of a dynamic scanning force microscope (dynamic SFM) are shown. Surfaces of highly ordered pyrolytic graphite (HOPG) were used as a test substrate since metal nanoclusters with well defined and symmetric shapes can be created by epitaxial growth. We performed imaging of gold clusters with sizes between 5 and 15 nm in both scanning modes, constant f mode and constant height mode, and compared the image contrast. We notice that clusters in constant height images appear much sharper, and exhibit more reasonable lateral shapes and sizes in comparison to images recorded in the constant f mode. With the help of numerical simulations we show that only a microscopically small part of the tip apex (nanotip) is probably the main contributor for the image contrast formation. In principle, the constant height mode can be used for imaging surfaces of any material, e.g. ionic crystals, as shown for the system Au/NaCl(001).

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Section: Samples and Instrumentsmentioning

confidence: 99%

“…For an in situ characterization and for substrates of insulating materials such as MgO or Al 2 O 3 , only the scanning force microscope can be used. Especially in its dynamic mode, the SFM offers in principle the ability to image surfaces with high resolution-in the best case with atomic resolution [5][6][7].…”

Section: Introductionmentioning

confidence: 99%

Imaging nanoclusters in theconstant height modeof the dynamic SFM

et al. 2006

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“…On binary and more complex ionic surfaces, the polarity of the tip apex determines whether anions or cations are imaged as protrusions [3]. Therefore, it is impossible to assign image features to particular surface atoms without knowing the tip polarity.…”

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confidence: 99%

“…The ability to characterize insulating surfaces and control surface processes down to the atomic scale is extremely important for numerous applications in chemistry, catalysis, nanoscience, and nanotechnology and can be achieved only using AFM. The exact chemical nature and structure of the AFM tip apex as well as the identity of the foremost tip atom are ultimately responsible for the formation of atomic-scale contrast [3], but are notoriously difficult to control. AFM tips are typically fabricated ex situ from silicon or metals and hence possess an oxide layer, either due to the manufacturing process itself or by oxidation in air.…”

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confidence: 99%

Chemical Resolution at Ionic Crystal Surfaces Using Dynamic Atomic Force Microscopy with Metallic Tips

Teobaldi

Lämmle²,

Trevethan

et al. 2011

Phys. Rev. Lett.

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We demonstrate that well prepared and characterized Cr tips can provide atomic resolution on the bulk NaCl(001) surface with dynamic atomic force microscopy in the noncontact regime at relatively large tip-sample separations. At these conditions, the surface chemical structure can be resolved yet tipsurface instabilities are absent. Our calculations demonstrate that chemical identification is unambiguous, because the interaction is always largest above the anions. This conclusion is generally valid for other polar surfaces, and can thus provide a new practical route for straightforward interpretation of atomically resolved images.

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“…25 This tip model has been widely used to simulate SFM imaging and provided good qualitative agreement with experiments on other ionic surfaces. 26 For this work, calculations were performed using both MgO and NaCl tips, each consisting of a cubic cluster of 32 cations and 32 anions with stable ͕100͖ facets oriented such that ͗111͘ direction is perpendicular to the sample surface. Ions in the top half of the cluster were kept fixed.…”

Section: B Theoreticalmentioning

confidence: 99%

Site-specific force-distance characteristics on NaCl(001): Measurements versus atomistic simulations

et al. 2006

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A scanning force microscope was used to measure the frequency shift above various atomic sites on a NaCl͑001͒ surface at 7 K. The data was converted to force and compared to the results of atomistic simulations using model NaCl and MgO tips. We find that the NaCl tip demonstrates better agreement in the magnitude of the forces in experiments, supporting the observation that the tip first came into contact with the sample. Using the MgO tip as a model of the originally oxidized silicon tip, we further demonstrate a possible mechanism for tip contamination at low temperatures.

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Theories of scanning probe microscopes at the atomic scale

Cited by 447 publications

References 225 publications

Imaging nanoclusters in theconstant height modeof the dynamic SFM

Imaging nanoclusters in theconstant height modeof the dynamic SFM

Chemical Resolution at Ionic Crystal Surfaces Using Dynamic Atomic Force Microscopy with Metallic Tips

Site-specific force-distance characteristics on NaCl(001): Measurements versus atomistic simulations

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