The Attachment of Carbon Nanotubes to Atomic Force Microscopy Tips Using the Pick-Up Method

Gibson, Christopher T.

doi:10.3390/app10165575

Cited by 7 publications

(3 citation statements)

References 73 publications

(89 reference statements)

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“…Nano‐sized electronic devices, such as nanotube field‐effect transistors (NTFETs), have also been achieved 5 . Moreover, because of their small size, CNTs can improve the resolution in scanning tunneling and atomic force microscopes, as well as other scanning probe instruments 6–9 …”

Section: Introductionmentioning

confidence: 99%

Carbon nanotube‐polybutadiene‐poly(ethylene oxide)‐based composite fibers: Role of cryogenic treatment on intrinsic properties

Gürbüz

Sarac

Soprunyuk

et al. 2022

Polymers for Advanced Techs

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The low‐temperature response and the notion of crystallization kinetics are critical for developing elastomeric composite fibers, thus the crystallization and mechanical properties are essential for the application of composites of polybutadiene at low temperatures. Despite the high amount of fiber joining and entanglement due to polymers' low glass transition, a defect‐free micro‐scale electrospun carbon nanotube (CNT)‐containing poly(ethylene oxide) (PEO) and polybutadiene (PBu) composite elastomeric fibers with uniform fiber diameter and distribution are successfully fabricated. Thermomechanical behavior analyzed via frequency‐dependent dynamic mechanical analysis under cryogenic conditions shows a remarkable increase in decomposition temperatures (Tend) and storage and loss modulus at cryogenic temperatures, particularly when small amounts of CNTs are present. Dynamic mechanical treatment from 120 K to elevated temperatures yields a pronounced logarithmic increase in Tend by an increase of PEO content (from BEC1 to BEC4) compared to the treatment from 300 K. Through X‐ray diffraction, large shifts toward larger 2θ and formation of new crystals are observed, particularly for the BEC4 sample with high PEO content. Nanoparticles after cryo‐treatment linked with crystallinity are registered by ultra‐high resolution scanning electron microscopy. Improving the thermal and mechanical properties is critical in developing high‐performance composite fibers for cryogenic engineering applications, especially for future research to facilitate them in aerospace and low‐temperature medical and surgical treatments.

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Section: Introductionmentioning

confidence: 99%

Carbon nanotube‐polybutadiene‐poly(ethylene oxide)‐based composite fibers: Role of cryogenic treatment on intrinsic properties

Gürbüz

Sarac

Soprunyuk

et al. 2022

Polymers for Advanced Techs

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“…Since, individual CNT cannot be observed with an optical microscope of limited resolution, the above-mentioned methods soon encountered difficulties in accurate manipulation. Another method is to grow CNT directly on AFM tip via chemical vapor deposition [2,15,16]. This method, however, has limitations in the length control of the grown CNT.…”

Section: Introductionmentioning

confidence: 99%

Advancement in fabrication of carbon nanotube tip for atomic force microscope using multi-axis nanomanipulator in scanning electron microscope

Kanth¹,

Sharma²,

Park³

et al. 2022

Nanotechnology

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We have constructed a new nanomanipulator (NM) in a field emission scanning electron microscope (FE-SEM) to fabricate carbon nanotube (CNT) tip to precisely adjust the length and attachment angle of CNT onto the mother atomic force microscope (AFM) tip. The new NM is composed of 2 modules, each of which has the degree of freedom of three-dimensional rectilinear motion x, y and z and one-dimensional rotational motion θ. The NM is mounted on the stage of a FE-SEM. With the system of 14 axes in total which includes 5 axes of FE-SEM and 9 axes of nano-actuators, it was possible to see CNT tip from both rear and side view about the mother tip. With the help of new NM, the attachment angle error could be reduced down to 0º as seen from both the side and the rear view, as well as, the length of the CNT could be adjusted with the precision using electron beam induced etching. For the proper attachment of CNT on the mother tip surface, the side of the mother tip was milled with focused ion beam. In addition, electron beam induced deposition was used to strengthen the adhesion between CNT and the mother tip. In order to check the structural integrity of fabricated CNT, transmission electron microscope image was taken which showed the fine cutting of CNT and the clean surface as well. Finally, the performance of the fabricated CNT tip was demonstrated by imaging 1-D grating and DNA samples with atomic force microscope in tapping mode.

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“…The CNT tip has 1-dimensional (1D) structure, ultrathin diameter, and high surface to volume ratio. Due to these properties, the use of CNT tip as a probe in Scanning Probe Microscopy (SPM) to detect tunneling current (in scanning tunneling microscopy) and interaction force (in atomic force microscopy) is on the rise, and it is possible to achieve atomic resolution easily and address their potential to improve lateral resolution [8][9][10][11].…”

Section: Introductionmentioning

confidence: 99%

Random telegraphic noise and 1/f noise from CNT emitters in Tuning fork-based scanning tunneling microscopy

Kolekar¹,

Dharmadhikari²

2021

Phys. Scr.

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In the present manuscript, we have investigated the fluctuations in the tunneling current (noise) from vertically aligned Carbon nanotube (CNT) emitters using home-built tuning-fork based Scanning Tunneling Microscopy/Spectroscopy (tf-STM/S). The fluctuations in the tunneling current are recorded in near field geometry (i. e. tunneling geometry, the distance between tip and CNT emitters is ∼1 nm) and in far field geometry (i.e. Fowler-Northeim tunneling (F-N), the distance between tip and CNT emitters is 100 nm). The recorded fluctuations in the tunneling current for near field are showing a Random Telegraphic Noise (RTN) and extrinsic 1/f type noise for various time domains. An observed fluctuation is explained with plausible mechanism of a two-level on-off trap state model. The average lifetime for the on state is τ 1 =3.36 sec, and for the off state τ 2 =0.89 sec. The calculated trap energy level is ΔE=0.034 eV. The calculated slope from the power spectral density plot ∼1.9 for RTN, and ∼1.1 for extrinsic 1/f type noise. Furthermore, the extrinsic 1/f type noise is observed in the tunneling current recorded in far field geometry, where the tunneling current is generated by tunneling of electrons through a triangular barrier. The calculated slope from power spectral density plot is ≈1.0. The understanding of noise from surface interface of CNTs is important in different tunneling geometries for device applications.

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The Attachment of Carbon Nanotubes to Atomic Force Microscopy Tips Using the Pick-Up Method

Cited by 7 publications

References 73 publications

Carbon nanotube‐polybutadiene‐poly(ethylene oxide)‐based composite fibers: Role of cryogenic treatment on intrinsic properties

Carbon nanotube‐polybutadiene‐poly(ethylene oxide)‐based composite fibers: Role of cryogenic treatment on intrinsic properties

Advancement in fabrication of carbon nanotube tip for atomic force microscope using multi-axis nanomanipulator in scanning electron microscope

Random telegraphic noise and 1/f noise from CNT emitters in Tuning fork-based scanning tunneling microscopy

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