330 research outputs found
Energy-filtered transmission electron microscopy of biological samples on highly transparent carbon nanomembranes
Ultrathin carbon nanomembranes (CNM) comprising crosslinked biphenyl
precursors have been tested as support films for energy-filtered transmission
electron microscopy (EFTEM) of biological specimens. Due to their high
transparency CNM are ideal substrates for electron energy loss spectroscopy
(EELS) and electron spectroscopic imaging (ESI) of stained and unstained
biological samples. Virtually background-free elemental maps of tobacco mosaic
virus (TMV) and ferritin have been obtained from samples supported by ~ 1 nm
thin CNM. Furthermore, we have tested conductive carbon nanomembranes (cCNM)
comprising nanocrystalline graphene, obtained by thermal treatment of CNM, as
supports for cryoEM of ice-embedded biological samples. We imaged ice-embedded
TMV on cCNM and compared the results with images of ice-embedded TMV on
conventional carbon film (CC), thus analyzing the gain in contrast for TMV on
cCNM in a quantitative manner. In addition we have developed a method for the
preparation of vitrified specimens, suspended over the holes of a conventional
holey carbon film, while backed by ultrathin cCNM
Fabrication of carbon nanomembranes by helium ion beam lithography
Zhang X, Vieker H, Beyer A, Gölzhäuser A. Fabrication of carbon nanomembranes by helium ion beam lithography. Beilstein Journal of Nanotechnology. 2014;5:188-194.The irradiation-induced cross-linking of aromatic self-assembled monolayers (SAMs) is a universal method for the fabrication of ultrathin carbon nanomembranes (CNMs). Here we demonstrate the cross-linking of aromatic SAMs due to exposure to helium ions. The distinction of cross-linked from non-cross-linked regions in the SAM was facilitated by transferring the irradiated SAM to a new substrate, which allowed for an ex situ observation of the cross-linking process by helium ion microscopy (HIM). In this way, three growth regimes of cross-linked areas were identified: formation of nuclei, one-dimensional (1D) and two-dimensional (2D) growth. The evaluation of the corresponding HIM images revealed the dose-dependent coverage, i.e., the relative monolayer area, whose density of cross-links surpassed a certain threshold value, as a function of the exposure dose. A complete cross-linking of aromatic SAMs by He+ ion irradiation requires an exposure dose of about 850 mu C/cm(2), which is roughly 60 times smaller than the corresponding electron irradiation dose. Most likely, this is due to the energy distribution of secondary electrons shifted to lower energies, which results in a more efficient dissociative electron attachment (DEA) process
TLC-SERS Plates with a Built-In SERS Layer Consisting of Cap-Shaped Noble Metal Nanoparticles Intended for Environmental Monitoring and Food Safety Assurance
Takei H, Saito J, Kato K, Vieker H, Beyer A, Gölzhäuser A. TLC-SERS Plates with a Built-In SERS Layer Consisting of Cap-Shaped Noble Metal Nanoparticles Intended for Environmental Monitoring and Food Safety Assurance. Journal of Nanomaterials. 2015;2015: 316189 .We report on a thin layer chromatograph (TLC) with a built-in surface enhanced Raman scattering (SERS) layer for in-situ identification of chemical species separated by TLC. Our goal is to monitor mixture samples or diluted target molecules suspended in a host material, as happens often in environmental monitoring or detection of food additives. We demonstrate that the TLC-SERS can separate mixture samples and provide in-situ SERS spectra. One sample investigated was a mixture consisting of equal portions of Raman-active chemical species, rhodamine 6 G (R6G), crystal violet (CV), and 1,2-di(4-pyridyl)ethylene (BPE). The three components could be separated and their SERS spectra were obtained from different locations. Another sample was skim milk with a trace amount of melamine. Without development, no characteristic peaks were observed, but after development, a peak was observed at 694 cm(-1). Unlike previous TLC-SERS whereby noble metal nanoparticles are added after development of a sample, having a built-in SERS layer greatly facilitates analysis as well as maintaining high uniformity of noble metal nanoparticles
Single-walled carbon nanotubes and nanocrystalline graphene reduce beam-induced movements in high-resolution electron cryo-microscopy of ice-embedded biological samples
For single particle electron cryo-microscopy (cryoEM), contrast loss due to
beam-induced charging and specimen movement is a serious problem, as the thin
films of vitreous ice spanning the holes of a holey carbon film are
particularly susceptible to beam-induced movement. We demonstrate that the
problem is at least partially solved by carbon nanotechnology. Doping
ice-embedded samples with single-walled carbon nanotubes (SWNT) in aqueous
suspension or adding nanocrystalline graphene supports, obtained by thermal
conversion of cross-linked self-assembled biphenyl precursors, significantly
reduces contrast loss in high-resolution cryoEM due to the excellent electrical
and mechanical properties of SWNTs and graphene
A two-dimensional magneto-optical trap of dysprosium atoms as a compact source for efficient loading of a narrow-line three-dimensional magneto-optical trap
We report on a scheme for loading dysprosium atoms into a narrow-line
three-dimensional magneto-optical trap (3D MOT). Our innovative approach
replaces the conventional Zeeman slower with a 2D MOT operating on the broad
421-nm line to create a high-flux beam of slow atoms. Even in the absence of a
push beam, we demonstrate efficient loading of the 3D MOT, which operates on
the narrower 626-nm intercombination line. Adding push beams working at either
421 nm or 626 nm, significant enhancement of the loading rate is achieved. We
reach the best performance, with an enhancement factor of , using a push
beam red-detuned to the 626-nm line. With loading rates greater than
atoms/s achieved at a moderate oven reservoir temperature of 800\,^{\circ}C,
our method offers similar or greater performance than Zeeman-slower-based
systems. Our 2D-MOT-based approach constitutes a promising first step for
state-of-the-art quantum gas experiments with several advantages over the
Zeeman-slower-based setup and is readily adaptable to other open-shell
lanthanides
Efficient electron-induced removal of oxalate ions and formation of copper nanoparticles from copper(II) oxalate precursor layers
Rueckriem K, Grotheer S, Vieker H, et al. Efficient electron-induced removal of oxalate ions and formation of copper nanoparticles from copper(II) oxalate precursor layers. BEILSTEIN JOURNAL OF NANOTECHNOLOGY. 2016;7:852-861.Copper(II) oxalate grown on carboxy-terminated self-assembled monolayers (SAM) using a step-by-step approach was used as precursor for the electron-induced synthesis of surface-supported copper nanoparticles. The precursor material was deposited by dipping the surfaces alternately in ethanolic solutions of copper(II) acetate and oxalic acid with intermediate thorough rinsing steps. The deposition of copper(II) oxalate and the efficient electron-induced removal of the oxalate ions was monitored by reflection absorption infrared spectroscopy (RAIRS). Helium ion microscopy (HIM) reveals the formation of spherical nanoparticles with well-defined size and X-ray photoelectron spectroscopy (XPS) confirms their metallic nature. Continued irradiation after depletion of oxalate does not lead to further particle growth giving evidence that nanoparticle formation is primarily controlled by the available amount of precursor
Imaging of carbon nanomembranes with helium ion microscopy
Beyer A, Vieker H, Klett R, Meyer Zu Theenhausen H, Angelova P, Gölzhäuser A. Imaging of carbon nanomembranes with helium ion microscopy. Beilstein Journal of Nanotechnology. 2015;6:1712-1720.Carbon nanomembranes (CNMs) prepared from aromatic self-assembled monolayers constitute a recently developed class of 2D materials. They are made by a combination of self-assembly, radiation-induced cross-linking and the detachment of the cross-linked SAM from its substrate. CNMs can be deposited on arbitrary substrates, including holey and perforated ones, as well as on metallic (transmission electron microscopy) grids. Therewith, freestanding membranes with a thickness of 1 nm and macroscopic lateral dimensions can be prepared. Although free-standing CNMs cannot be imaged by light microscopy, charged particle techniques can visualize them. However, CNMs are electrically insulating, which makes them sensitive to charging. We demonstrate that the helium ion microscope (HIM) is a good candidate for imaging freestanding CNMs due to its efficient charge compensation tool. Scanning with a beam of helium ions while recording the emitted secondary electrons generates the HIM images. The advantages of HIM are high resolution, high surface sensitivity and large depth of field. The effects of sample charging, imaging of multilayer CNMs as well as imaging artefacts are discussed
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