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During in situ transmission electron microscopy (TEM) field emission
experiments, carbon nanotubes are observed to strongly diffract the
imaging TEM electron beam. We demonstrate that this effect is identical
to that of a standard electrostatic biprism. We also demonstrate that
the nanotube biprism can be used to capture electron-holographic
information.
Mechanical properties, such as hardness and impact toughness, of
ferrite-containing stainless steels are greatly affected by long-term
aging at intermediate temperatures. It is known that the
α-α′ spinodal decomposition occurring in the
iron–chromium-based ferrite is responsible for this aging
susceptibility. This decomposition can be characterized unambiguously
by atom probe analysis, allowing comparison both with the existing
theories of spinodal decomposition and the evolution of some mechanical
properties. It is then possible to predict the evolution of hardness of
industrial components during service, based on the detailed knowledge
of the involved aging process.
Although acidocalcisomes have been well characterized morphologically
in other apicomplexan parasites, no such characterization has been done
in Plasmodium spp. Here, we report that Plasmodium falciparum
merozoites possess electron-dense organelles rich in phosphorus and
calcium, as detected by X-ray microanalysis of intact cells, which are
similar to the acidocalcisomes of other apicomplexans, but of more
irregular form. In agreement with these results malaria parasites
possess large amounts of short- and long-chain polyphosphate (polyP),
which are associated with acidocalcisomes in other organisms. PolyP
levels were highest in the trophozoite stage of the parasite. Treatment
of isolated trophozoites with chloroquine resulted in a significant
hydrolysis of polyP. Taken together, these results provide evidence
that acidocalcisomes from Plasmodium falciparum do not differ
significantly from acidocalcisomes of other apicomplexan parasites.
Paracoccidioidomycosis is a systemic granulomatous disease caused by
the dimorphic fungus Paracoccidioides brasiliensis. It is the
most prevalent systemic mycosis of Latin America and 80% of the
reported cases are from Brazil. Because of the great number of
neutrophils found in the P. brasiliensis granuloma, studies
have been done to evaluate the role of these cells during the
development of the infection. Scanning and transmission electron
microscopy of thin sections showed that the neutrophils ingest yeast
cells through a typical phagocytic process with the formation of
pseudopodes. The pseudopodes even disrupt the connection established
between the mother and the bud cells. Neutrophils also associate to
each other, forming a kind of extracellular vacuole where large yeast
cells are encapsulated. Cytochemical studies showed that once P.
brasiliensis attaches to the neutrophil surface, it triggers a
respiratory burst with release of oxygen-derived products. Attachment
also triggers neutrophils' degranulation, with release of
endogenous peroxidase localized in cytoplasmic granules. Together,
these processes lead to killing of both ingested and extracellular
P. brasiliensis.
High-resolution transmission (HRTEM) and high-resolution scanning
electron microscopy as well as atomic force microscopy (AFM), X-ray
diffraction, and electron diffraction were used for studying the
zeolites MFI, MEL, and the MFI/MEL intergrowth system. All three
zeolites consisted of individual particles having a size in the range
of approximately 0.5 μm to 5 μm. The particle habits varied
from rather cubelike to almost spherelike with many intermediate
habits. Typically, the particles of these three zeolites were assembled
by many individual blocks that differed in the dimension from about 25
nm to 140 nm as well as in the shape from very frequently almost
rectangular (for MFI, MEL, and MFI/MEL) to sometimes roundish or
irregular habits (mainly for MFI/MEL). An estimate shows that some
104 up to more than 106 densely packed blocks
typically may assemble each individual zeolite particle or, related to
the corresponding unit cell dimension, about 108 up to
1010 unit cells. The fine surface structure of zeolite
particles was terracelike with steps between adjacent terraces
typically in the range of 20 nm to 60 nm; the minimum step measured was
approximately 4 nm. A detailed study of the surface topography was
performed by AFM, detecting organic molecules at the block
intersections. The presence of topological defects was observed by
HRTEM and electron diffraction.
The key contribution of electron microscopy methods to condensed
matter spectroscopy is undoubtedly spatial resolution. So far this has
mainly been manifest through electron energy loss spectroscopy in the
1-eV to 10-keV energy range and has not seriously challenged the
dominance of optical, X-ray, and neutron spectroscopy methods over most
of the vast field at lower energies. At frequencies up to a few
megahertz, corresponding to energies of a few nanoelectron volts and
below, direct excitation by pulsed electron beams or electric fields
has proved effective. Prospects are discussed for extending spatially
resolved spectroscopy to the intermediate energy region, mainly by
combining the advantages of electrons with those of photons.
Extended abstract of a paper presented at the Pre-Meeting Congress: Materials Research in an Aberration-Free Environment, at Microscopy and Microanalysis 2004 in Savannah, Georgia, USA, July 31 and August 1, 2004.
A general method is presented for determining and correcting
nonlinear position detector responses in single particle tracking as
used in three-dimensional scanning probe microscopy based on optical
tweezers. The method uses locally calculated mean square displacements
of a Brownian particle to detect spatial changes in the sensitivity of
the detector. The method is applied to an optical tweezers setup, where
the position fluctuations of a microsphere within the optical trap are
measured by an interferometric detection scheme with nanometer
precision and microsecond temporal resolution. Detector sensitivity
profiles were measured at arbitrary positions in solution with a
resolution of approximately 6 nm and 20 nm in the lateral and axial
directions, respectively. Local detector sensitivities are used to
reconstruct the real positions of the particle from the measured
position signals.
A framework is presented for understanding charging processes in low
vacuum scanning electron microscopy. We consider the effects of
electric fields generated above and below the specimen surface and
their effects on various processes taking place in the system. These
processes include the formation of an ionic space charge,
field-enhanced electron emission, charge trapping and dissipation, and
electron–ion recombination. The physical mechanisms behind each
of these processes are discussed, as are the microscope operating
conditions under which each process is most effective. Readily
observable effects on gas gain curves, secondary electron images, and
X-ray spectra are discussed.
The influence of W on the temporal evolution of γ′
precipitation toward equilibrium in a model Ni-Al-Cr alloy is
investigated by three-dimensional atom-probe (3DAP) microscopy and
transmission electron microscopy (TEM). We report on the alloys Ni-10
Al-8.5 Cr (at.%) and Ni-10 Al-8.5 Cr-2 W (at.%), which were aged
isothermally in the γ + γ′ two-phase field at 1073 K, for
times ranging from 0.25 to 264 h. Spheroidal-shaped γ′
precipitates, 5–15 nm diameter, form during quenching from above
the solvus temperature in both alloys at a high number density
(∼1023 m−3). As γ′
precipitates grow with aging at 1073 K, a transition from spheriodal-
to cuboidal-shaped precipitates is observed in both alloys. The
elemental partitioning and spatially resolved concentration profiles
across the γ′ precipitates are obtained as a function of
aging time from three-dimensional atom-by-atom reconstructions.
Proximity histogram concentration profiles (Hellman
et al., 2000) of the quaternary alloy demonstrate that W
concentration gradients exist in γ′ precipitates in the
as-quenched and 0.25-h aging states, which disappear after 1 h of
aging. The diffusion coefficient of W in γ′ is estimated to
be 6.2 × 10−20 m2
s−1 at 1073 K. The W addition decreases the coarsening
rate constant, and leads to stronger partitioning of Al to γ′
and Cr to γ.
The ability to transfect Apicomplexan parasites has revolutionized
the study of this important group of pathogens. The function of
specific genes can be explored by disruption of the locus or more
subtly by introduction of altered or tagged versions. Using the
transgenic reporter gene green fluorescent protein (GFP), cell
biological processes can now be studied in living parasites and in real
time. We review recent advances made using GFP-based experiments in the
understanding of protein trafficking, organelle biogenesis, and cell
division in Toxoplasma gondii and Plasmodium
falciparum. A technical section provides a collection of basic
experimental protocols for fluorescent protein expression in T.
gondii. The combination of the in vivo marker GFP with an
increasingly diverse genetic toolbox for T. gondii opens many
exciting experimental opportunities, and emerging applications of GFP
in genetic and pharmacological screens are discussed.
Extended abstract of a paper presented at the Pre-Meeting Congress: Materials Research in an Aberration-Free Environment, at Microscopy and Microanalysis 2004 in Savannah, Georgia, USA, July 31 and August 1, 2004.
The variable pressure scanning electron microscope (VP-SEM) allows
imaging of insulators without the need for a conductive coating, due to
charge neutralization at the surface from recombination of positive
ions and surface electrons. Varying certain parameters such as
pressure, bias, and working distance creates incomplete neutralization,
and localized charging develops called charge contrast. Although the
exact mechanism creating charge contrast imaging (CCI) is unknown, it
is agreed that it is related to an optimum charge compensation. The
behavior of the CCI is still vague, which presents a problem for
determining the mechanisms. This article provides user-friendly methods
of finding the optimum levels of charge contrast in the VP-SEM. We show
that the CCI is obtained at optimum operating conditions where the
specimen current is between 2.5 nA and 3.5 nA. The specimen current is
a function of secondary electrons (SE) emission and ionization
potential, producing an ion flux. Therefore an optimum specimen current
represents the balanced conditions of SE emission and ion flux.
Controlling the pressure, working distance, bias, scan rate, and beam
current allows the microscopist to set the specimen current at this
optimum level for charge contrast imaging. All the work was performed
on gibbsite using the S3000N VP-SEM from Hitachi.
The Executive Program Group for Microscopy and Microanalysis
(M&M) 2004 set out with the challenge of drafting a compelling
scientific program for the annual meetings of the Microscopy Society of
America (MSA) and the Microbeam Analysis Society (MAS) that would be
equal to the excitement of organizational change being discussed by the
societies. We feel that we have met the challenge, providing a diverse
and balanced program that looks forward to new opportunities and
presents the current state-of-the-art for microscopy and microanalysis.
For the third consecutive year, the program is strengthened by the
co-sponsorship of the International Metallographic Society (IMS), which
is fast becoming an annual partner in the M&M meetings.
A review of transmission electron microscopy studies of planar
defects in 18R and 2H martensites in Cu-Zn-Al alloys is presented. The
non-basal plane faults observed in the 2H structure, the F1
faults, show two kinds of dislocations at their ends. In contrast, two
types of non-basal plane faults are observed in the 18R structure,
Fo and Fx faults. The non-basal plane faults can
be composed of segments of Fo and Fx faults. Six
types of imperfect dislocations appear, depending on the type of basal
plane fault ending at the non-basal plane fault. The Burgers vectors of
all these dislocations have been determined from the contrast analysis
of the images and HREM observations.
The first paper on the FFT multislice method was published in 1977, a
quarter of a century ago. The formula was extended in 1982 to include a
large tilt of an incident beam relative to the specimen surface. Since
then, with advances of computing power, the FFT multislice method has
been successfully applied to coherent CBED and HAADF-STEM simulations.
However, because the multislice formula is built on some physical
approximations and approximations in numerical procedure, there seem to
be controversial conclusions in the literature on the multislice
method. In this report, the physical implication of the multislice
method is reviewed based on the formula for the tilted illumination.
Then, some results on the coherent CBED and the HAADF-STEM simulations
are presented.