Leica Microsystems EM ACE600 Application Note

Type
Application Note

Leica Microsystems EM ACE600 is a versatile, easy-to-use carbon coater for a wide range of applications in the life sciences and materials science. The EM ACE600 enables high-quality, reproducible carbon coating for improved imaging and analysis in transmission electron microscopy (TEM). With its unique combination of flexibility, accuracy, and reproducibility, the EM ACE600 is the ideal solution for preparing ultra-thin carbon films for TEM specimen preparation.

Key features of the Leica Microsystems EM ACE600:

  • Adaptive carbon thread evaporation: Ensures precise and flexible carbon coating, enabling the preparation of ultra-thin carbon films with high accuracy and reproducibility.

Leica Microsystems EM ACE600 is a versatile, easy-to-use carbon coater for a wide range of applications in the life sciences and materials science. The EM ACE600 enables high-quality, reproducible carbon coating for improved imaging and analysis in transmission electron microscopy (TEM). With its unique combination of flexibility, accuracy, and reproducibility, the EM ACE600 is the ideal solution for preparing ultra-thin carbon films for TEM specimen preparation.

Key features of the Leica Microsystems EM ACE600:

  • Adaptive carbon thread evaporation: Ensures precise and flexible carbon coating, enabling the preparation of ultra-thin carbon films with high accuracy and reproducibility.
Application Note
Ultra-Thin Carbon Films
related instruments: Leica EM ACE600
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Ways to Reveal More form your Samples:
Ultra-Thin Carbon Films
Much of the battle involved in obtaining good transmission electron
microscopy data is in the specimen preparation itself. Even though
some nanomaterials are already electron transparent (e.g.
nanoparticles and proteins) and often do not require further thinning
procedures, they need to be dispersed onto thin support films.
Carbon films provide a continuous electron transparent support
enabling the analysis of specimens without excessive interference
from underlying support material. The quality and characteristics of
such carbon support films have a major influence on the analysis,
whether studying nanomaterials or biological nanostructures. This
application note describes the process of preparing ultra-thin carbon
films in a reproducible manner. These support films can be used for
a wide variety of nanostructures and allow to obtain a complete
insight into the specimens being studied.
CARBON FILMS: HOW TO DEFINE 'QUALITY'?
Carbon films are preferred because of their mechanical strength,
conductivity and thermostability. The preparation of ultra-thin
carbon films in a straightforward manner can be a laborious task
owing to the non-reproducible characteristics of conventional
carbon deposition methods. The structure and quality of the carbon
films are governed by the evaporation characteristics (evaporation
mode, vacuum level, evaporation rate, work distance and
temperature). Before going into detail on these parameters or on the
evaporation of high quality amorphous carbon films, it is essential
to define the term ‘quality’ and hence to discuss which criteria the
carbon support films should fulfill in order to be suitable for a broad
range of electron microscopy applications.
High transparency to electrons: the thickness and density of the
support film has an important effect on the contrast and
resolution of the image. When mass thickness is comparable to
that of the specimen the film can attenuate the intensity of
structural details in the image.
Adequate strength to withstand electron bombardment
Uniform thickness. Film thickness is crucial for analytical
investigations, quantitative imaging, or electron tomography.
Free of any intrinsic structures, surface irregularities and
contaminants
Conductive, in order to prevent the accumulation of charges
Easy to prepare and reproducible
Nevertheless, obtaining such carbon films is only the first step in the
process of making a suitable TEM specimen. In a second step, the
sample needs to be applied on the carbon support film. Samples are
usually dispersed in water or a solvent. Unfortunately, dispersions
in solvents often contain remaining reaction products (e.g.
surfactants, capping agents …) which are hard to eliminate and are
a source of contamination. Even though the carbon films were clean
prior to the application of the sample, the sample itself introduces
contaminants which can diffuse across the carbon surface to the
area of interest where they locally decompose and polymerize under
the electron beam. This carbon build-up results in poor signal
strength. Obviously, the carbon support films should fulfill some
additional criteria when used for TEM specimen preparation:
If the sample is dispersed in water, the support film should be
rendered hydrophilic using a glow discharge or mild plasma
treatment. Such treatments are essential in order to disperse
nanomaterials or biological structures more evenly and may
not damage the carbon film.
The support film should be mechanically stable because it can
undergo excessive handling during a specific protocol.
The support film should withstand other post-treatments e.g.
high vacuum heating in order to remove contaminants
Taking the above mentioned criteria into account, it is clear that a
trade-off exists between thickness and stability. Recently graphene
is used as a support film, however coating a complete holey carbon
film with graphene can be challenging and in terms of stability (e.g.
300 kV measurement, increased acquisition times, excessive grid
handling…), ultra-thin carbon films are preferred. To obtain a good
stability and charge dissipation, the ultra-thin carbon film should be
supported onto a holey carbon film, Quantifoil or a mesh grid (> 600
mesh grid). Unsupported ultra-thin films will show local deviations
from planarity and can break during electron beam irradiation or
handling.
Briefly, two steps in the preparation are crucial:
(1) obtaining a ‘high quality’ thin carbon film on a substrate and
(2) subsequently transferring this film onto a suitable support
structure.
2
EVAPORATING ULTRA-THIN FILMS ON A SUBSTRATE
Several approaches are used in order to prepare ultra-thin carbon
films. Typically, a 5 nm layer of amorphous carbon is evaporated
onto a polymeric support film (Formvar, Butvar, Collodion, ...) and
subsequently only the polymeric film is dissolved. This method,
however, introduces wrinkling of the remaining carbon film.
Additionally, not all of the polymer is dissolved causing the film
to be not uniform or clean. The most suitable and thinnest films
can be prepared by evaporating a carbon film directly onto freshly
cleaved mica. This film is released in water and transferred onto
a Quantifoil or holey carbon film. The supporting structure is
necessary in order to improve the stability and charge dissipation
and limit vibrations during imaging.
Amorphous carbon films can be obtained through different carbon
evaporation modes. Arc-evaporation of pre-shaped graphitic rods
is the most widespread technique to obtain amorphous carbon
films. Macroparticles associated with the arc process are often
seen in the deposited films and result in increased thickness
irregularity. Another disadvantage is the high temperature during
evaporation (radiant heat), which can damage sensitive samples,
result in wrinkled carbon films but more important in larger average
sizes of the carbon clusters in the film. The large pressure rise
during evaporation even further contributes to the formation of
these clusters (increase in granularity). As a result a severe
surface roughness is observed in films with a thickness of 3 to 5
nm. The large heat also affects the frequency of the oscillating
quartz crystal, making accurate and reproducible layer deposition
difficult. Moreover, the high energetic evaporated carbon species
impact the sample, causing a strong adherence which makes
releasing the carbon film from the mica substrate difficult.
Obviously carbon rod evaporation is not the most optimal method
to produce smooth ultrathin 3 nm carbon films in a reproducible
manner.
ADAPTIVE CARBON THREAD EVAPORATION:FLEXIBLE,
ACCURATE AND REPRODUCIBLE
Adaptive carbon thread evaporation enables a precise and flexible
carbon coating of which its applicability far exceeds that of the
ultrathin carbon films shown in this application note. Its
unparalleled flexibility originates from its unique adaptive process
and multi-segment configuration. However, not only the evaporation
mode but also the underlying electronics are crucial, especially
when evaporating the thinnest films where uniformity and accuracy
are of the outmost importance. The ultra-thin carbon films are
obtained through multiple evaporation. The multi-segment
configuration allows to evaporate carbon from 4 carbon thread
segments. This enables the use of thin carbon threads and results
in the highest accuracy as all layers are build up sequentially
through adaptive pulsing.
Between each pulse, the thickness of the carbon film and properties
of the remaining carbon thread segment are measured in order to
adapt the parameters for the next pulse. The high vacuum (5x10-6
mbar) and stable vacuum during evaporation allow the deposition
of uniform ultra-thin carbon layers. The deposited films are free of
any intrinsic structures, surface irregularities and contaminants.
Moreover, radiant heat to the sample is decreased considerably. In
the image shown above, consecutive layers were deposited on a
filter paper (from left to right: 1, 2, 3, 4 and 5 nm). Carbon thread
evaporation is also uniform over a large area (see images below).
A round filter paper of approximately 10 cm is shown before (A)
and after (B) carbon coating.
Even more important is the combination of flexibility and
reproducibility. Properties of amorphous carbon films are strongly
dependent on the evaporation characteristics as e.g. evaporation
rate, vacuum, mode used etc. Once an evaporation protocol is
optimized and stored, reproducible results can be expected coating
after coating, without surprises. This reproducibility is crucial,
considering the fact that carbon coating is always a part of an
elaborate specimen preparation workflow.
3
LNT Application Note - ULTRA THIN CARBON FILMS
ULTRA-THIN CARBON FILMS: PROCEDURE
A A clean glass petri dish is filled with ultra-pure water.
B A filter paper is placed in the bottom of the petri dish and
Quantifoils or holey carbon films are carefully placed on the filter
paper.
C Using the adaptive carbon thread evaporation mode, a 3 nm
layer of carbon is deposited onto freshly cleaved mica at a vacuum
level of 5x10-6 mbar. Next, the carbon coated mica foil is lowered
slowly into the water at an angle of 30 degrees. Water will
penetrate the space between the carbon film and mica surface
through capillary forces and the film is released.
D The filter paper is slowly withdrawn out of the water assuring
that the square carbon film is deposited onto the grids.
E The filter paper is transferred onto a new filter paper in order
to drain most of the water before drying it on a hotplate of 40
degrees for 10 minutes.
F The films are ready to be used.
In contrast to the supporting Quantifoil film (see image F) the
ultrathin films covering the holes are impeccably clean and
uniform. The best procedure to prepare a TEM specimen by
applying a dispersion of any sample is to hold the grid with a
tweezer and apply a small drop of approximately 5 µl. Next, the
excess is blotted away by touching the edge of the grid on a filter
paper. If required the ultra-thin carbon film can be glow discharged
or plasma cleaned (low power and only 5% oxygen for
approximately 30 seconds). Below the difference can be seen
between a conventional carbon film (left, 15 nm carbon) and an
ultra-thin carbon film (right, 3 nm). The lattice of the CdSe quantum
plates can be easily observed in the right image.
Images acquired by Eva Bladt and Sara Bals (EMAT, University of
Antwerp)
Courtesy of: Frederic Leroux and Jan de Weert
Sample courtesy of: Daniel Vanmaekelbergh,
Debye Institute for Nanomaterials Science, University of Utrecht
4
RELATED PRODUCTS
Leica EM ACE600
Leica EM ICE Application Note ULTRA THIN CARBON FILMS06/16 ∙ Copyright © by Leica Mikrosysteme GmbH, Vienna, Austria, 2015. Subject to modifications. LEICA and the Leica Logo are registered trademarks of Leica Microsystems IR GmbH.
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Leica Microsystems EM ACE600 Application Note

Type
Application Note

Leica Microsystems EM ACE600 is a versatile, easy-to-use carbon coater for a wide range of applications in the life sciences and materials science. The EM ACE600 enables high-quality, reproducible carbon coating for improved imaging and analysis in transmission electron microscopy (TEM). With its unique combination of flexibility, accuracy, and reproducibility, the EM ACE600 is the ideal solution for preparing ultra-thin carbon films for TEM specimen preparation.

Key features of the Leica Microsystems EM ACE600:

  • Adaptive carbon thread evaporation: Ensures precise and flexible carbon coating, enabling the preparation of ultra-thin carbon films with high accuracy and reproducibility.

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