A versatile atomic force microscope integrated with a scanning electron microscope

Kreith, Josef; Strunz, Torsten; Fantner, E.J.; Fantner, Georg E.; Cordill, Megan J.

doi:10.1063/1.4983317

Cited by 23 publications

(19 citation statements)

References 33 publications

(40 reference statements)

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“…Prohibitively large instruments with optical readout are difficult to integrate into electron or ion microscopes and re-alignment of the optics is very impractical, as it requires the user to vent the chamber. Using self-sensing readout addresses these concerns [5,10,17] and also significantly improves the usability of the correlative instrument for users outside of the AFM community. The reported AFM uses silicon cantilever probes with boron-doped 1 kΩ sensing elements, connected in a Wheatstone bridge configuration with aluminum tracks [20,21] and with single crystal diamond (SCD) tips that are commercially available (SCL-SensorTech Fabrication GMBH, Vienna, Austria).…”

Section: Instrumentationmentioning

confidence: 99%

“…The prototype tip-scanning AFM scan head is designed explicitly for correlative analysis inside electron and ion-beam microscopes. Unlike sample scanning solutions [ 9 , 16 ], where the sample is raster-scanned relative to a stationary cantilever, a tip-scanning configuration [ 10 , 17 ] requires no alteration of the sample stage and has the advantage of having the sample stationary within the field of view of the HIM during AFM imaging. The scanner is a flexure design with serial kinematics [ 18 ] and the cantilever is mounted at the end of a low-profile protruding z -flexure, which fits seamlessly between the pole piece and the sample.…”

Section: Instrumentationmentioning

confidence: 99%

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An atomic force microscope integrated with a helium ion microscope for correlative nanoscale characterization

Andany

Hlawacek

Hummel³

et al. 2020

Beilstein J. Nanotechnol.

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In this work, we report on the integration of an atomic force microscope (AFM) into a helium ion microscope (HIM). The HIM is a powerful instrument, capable of imaging and machining of nanoscale structures with sub-nanometer resolution, while the AFM is a well-established versatile tool for multiparametric nanoscale characterization. Combining the two techniques opens the way for unprecedented in situ correlative analysis at the nanoscale. Nanomachining and analysis can be performed without contamination of the sample and environmental changes between processing steps. The practicality of the resulting tool lies in the complementarity of the two techniques. The AFM offers not only true 3D topography maps, something the HIM can only provide in an indirect way, but also allows for nanomechanical property mapping, as well as for electrical and magnetic characterization of the sample after focused ion beam materials modification with the HIM. The experimental setup is described and evaluated through a series of correlative experiments, demonstrating the feasibility of the integration.

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Section: Instrumentationmentioning

confidence: 99%

Section: Instrumentationmentioning

confidence: 99%

An atomic force microscope integrated with a helium ion microscope for correlative nanoscale characterization

Andany

Hlawacek

Hummel³

et al. 2020

Beilstein J. Nanotechnol.

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“…The installation of strain sensors directly into the cantilever is of particular interest as it offers several advantages over techniques with external readout. Some of the most important advantages are: (i) extremely small cantilevers far below the optical diffraction limit to increase sensitivity and so imaging speed can be realized [ 32 , 33 ], (ii) avoiding interference with photosensitive samples, (iii) the possibility of multi-cantilever arrays [ 34 , 35 , 36 ] and (iv) combining AFM with other techniques, such as scanning electron microscopy (SEM) [ 37 , 38 , 39 , 40 ]. In addition to the new readout method, advances in microfabrication have allowed the direct integration of actuators on the cantilever, such as piezoelectric excitation [ 41 ], Lorentz excitation [ 42 ], magnetic excitation [ 43 , 44 , 45 , 46 ] and thermal excitation [ 47 ].…”

Section: Introductionmentioning

confidence: 99%

“…Efforts over the last 20 years to further optimize strain sensor readout have resulted in piezoresistive cantilevers that exceed standard optical beam readout in terms of low-noise imaging [ 15 ]. Furthermore, a large number of different applications in the AFM field [ 35 , 37 , 38 , 40 , 50 , 51 , 52 ], but also for other cantilever sensor techniques, such as torque magnetometry [ 53 ] or gas sensors [ 54 ], have been published. Although there is a great potential for the use of self-sensing AFM cantilevers in bio-applications, only very few attempts have been documented to use them in liquid [ 55 ] or for imaging biological samples in liquid [ 56 ].…”

Section: Introductionmentioning

confidence: 99%

Atomic Force Microscopy Imaging in Turbid Liquids: A Promising Tool in Nanomedicine

Leitner

Seferovic

Stainer

et al. 2020

Sensors

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Tracking of biological and physiological processes on the nanoscale is a central part of the growing field of nanomedicine. Although atomic force microscopy (AFM) is one of the most appropriate techniques in this area, investigations in non-transparent fluids such as human blood are not possible with conventional AFMs due to limitations caused by the optical readout. Here, we show a promising approach based on self-sensing cantilevers (SSC) as a replacement for optical readout in biological AFM imaging. Piezo-resistors, in the form of a Wheatstone bridge, are embedded into the cantilever, whereas two of them are placed at the bending edge. This enables the deflection of the cantilever to be precisely recorded by measuring the changes in resistance. Furthermore, the conventional acoustic or magnetic vibration excitation in intermittent contact mode can be replaced by a thermal excitation using a heating loop. We show further developments of existing approaches enabling stable measurements in turbid liquids. Different readout and excitation methods are compared under various environmental conditions, ranging from dry state to human blood. To demonstrate the applicability of our laser-free bio-AFM for nanomedical research, we have selected the hemostatic process of blood coagulation as well as ultra-flat red blood cells in different turbid fluids. Furthermore, the effects on noise and scanning speed of different media are compared. The technical realization is shown (1) on a conventional optical beam deflection (OBD)-based AFM, where we replaced the optical part by a new SSC nose cone, and (2) on an all-electric AFM, which we adapted for measurements in turbid liquids.

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“…It allows direct in-situ combination of these complementary techniques due to the simultaneous operation of SEM and AFM inside the vacuum chamber. [1,2] Therefore, SEM imaging, chemical information by EDX, real 3D topography, phase information, mechanical, electrical, and magnetic properties by AFM can be combined in an easy and interactive way. Furthermore, due to the open design it can be combined with additional add-ons, e.g., tensile stages, nano-indentors [2] or nano-manipulators ( Figure 1a).…”

mentioning

confidence: 99%

Correlative In-Situ Analysis on the Nanoscale by combination of AFM and SEM

Winhold¹,

Leitner²,

Frank³

et al. 2018

Microsc Microanal

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A versatile atomic force microscope integrated with a scanning electron microscope

Cited by 23 publications

References 33 publications

An atomic force microscope integrated with a helium ion microscope for correlative nanoscale characterization

An atomic force microscope integrated with a helium ion microscope for correlative nanoscale characterization

Atomic Force Microscopy Imaging in Turbid Liquids: A Promising Tool in Nanomedicine

Correlative In-Situ Analysis on the Nanoscale by combination of AFM and SEM

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