Comparison of force sensors for atomic force microscopy based on quartz tuning forks and length-extensional resonators

Giessibl, Franz J.; Pielmeier, Florian; Eguchi, Toyoaki; An, Toshu; Hasegawa, Yukio

doi:10.1103/physrevb.84.125409

Cited by 102 publications

(99 citation statements)

References 54 publications

(127 reference statements)

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“…We use qPlus sensors which are self-sensing and based on quartz tuning forks. 20,21,24 The qPlus sensor was originally used in ambient environments, 24 and since the year 2000 when we obtained atomic resolution in UHV, 20 we tried to achieve atomic resolution in ambient conditions as well. A unique feature of our setup is the length of the bulk tips we use.…”

Section: A Fm-afm Cantilever a Damped Harmonic Oscillatormentioning

confidence: 99%

Optimizing atomic resolution of force microscopy in ambient conditions

2013

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Ambient operation poses a challenge to atomic force microscopy because in contrast to operation in vacuum or liquid environments, the cantilever dynamics change dramatically from oscillating in air to oscillating in a hydration layer when probing the sample. We demonstrate atomic resolution by imaging of the KBr(001) surface in ambient conditions by frequency-modulation atomic force microscopy with a cantilever based on a quartz tuning fork (qPlus sensor) and analyze both long-and short-range contributions to the damping. The thickness of the hydration layer increases with relative humidity; thus varying humidity enables us to study the influence of the hydration layer thickness on cantilever damping. Starting with measurements of damping versus amplitude, we analyzed the signal and the noise characteristics at the atomic scale. We then determined the optimal amplitude which enabled us to acquire high-quality atomically resolved images.

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Section: A Fm-afm Cantilever a Damped Harmonic Oscillatormentioning

confidence: 99%

Optimizing atomic resolution of force microscopy in ambient conditions

2013

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“…Hence, this tuning fork approach has the advantage that excitation and sensing can be achieved with the same unit. Recent designs achieved a deflection noise floor on the order of 5 Á 10 À14 m Hz À1/2 [71]. Other examples are cantilevers made out of piezoresistive materials, which change their resistance upon deflection [72,73].…”

Section: Detection Of Cantilever Oscillationmentioning

confidence: 98%

Imaging and Characterization of Magnetic Micro- and Nanostructures Using Force Microscopy

Block

2015

Surface Science Tools for Nanomaterials Characterization

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“…For this reason a completely electrical excitation and detection is desirable. This can be achieved by quartz crystal sensors like the tuning fork sensor 15 or the needle sensor. We have chosen the needle sensor, because of its small Rev.…”

Section: The Koaladrive Multitip Stmmentioning

confidence: 99%

Ultra compact multitip scanning tunneling microscope with a diameter of 50 mm

Cherepanov¹,

Zubkov²,

Junker³

et al. 2012

Review of Scientific Instruments

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We present a multitip scanning tunneling microscope (STM) where four independent STM units are integrated on a diameter of 50 mm. The coarse positioning of the tips is done under the control of an optical microscope or scanning electron microscopy in vacuum. The heart of this STM is a new type of piezoelectric coarse approach called KoalaDrive. The compactness of the KoalaDrive allows building a four-tip STM as small as a single-tip STM with a drift of less than 0.2 nm/min at room temperature and lowest resonance frequencies of 2.5 kHz (xy) and 5.5 kHz (z). We present as examples of the performance of the multitip STM four point measurements of silicide nanowires and graphene.

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Comparison of force sensors for atomic force microscopy based on quartz tuning forks and length-extensional resonators

Cited by 102 publications

References 54 publications

Optimizing atomic resolution of force microscopy in ambient conditions

Optimizing atomic resolution of force microscopy in ambient conditions

Imaging and Characterization of Magnetic Micro- and Nanostructures Using Force Microscopy

Ultra compact multitip scanning tunneling microscope with a diameter of 50 mm

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