Unblocking The Main Thread Solving ANRs and Frozen Frames
TEM versatile tool (small version)
1. Assignment on:
Describe the TEM as a versatile tool for
research in Nanotechnology. How can the
TEM be used to study crystal defects?
Name : Mohit Rajput
Enrolment no. : 12216014
Batch : mt5, tb3
2. Describe the TEM as a versatile tool for research in
Nanotechnology. How can the TEM be used to study crystal
defects?
As the dimensions of materials developed are reduced, therefore use in the semiconductor
industry of transmission electron microscopes (TEM) have become essential for
characterization. Currently we require high resolution observation and analysis of defects,
materials and structures with nanometer dimensions. The TEM is a popular choice for
nanotechnology as well as semiconductor analysis and production. This type of physical
characterization was traditionally dedicated to advanced characterization due to the destructive
nature of specimen preparation, as well as the fact that it was delicate and time consuming.
More recently, it has been shown that TEM can be performed on specimens and can overcome
past challenges such as cycle time and cost.
What is transmission electron microscopy?
The transmission electron microscope (TEM), the first type of Electron Microscope (EM)
which is an analytical tool allowing visualisation and analysis of specimens in the realms of
microspace (1 micron/1μm = 10-6
m) to nanospace (1 nanometer/nm = 10-9
m). The TEM
reveals levels of detail and complexity inaccessible by light microscopy because it uses a
focused beam of high energy electrons which is allowed by detailed micro-structural
3. examination through high-resolution and high magnification of specimen through black and
white 2D images which can be seen on a screen or printed onto a photographic plate allowing
for a wide range of educational, science and industry applications. It also enables the
investigation of crystal structures, specimen orientations and chemical compositions of phases,
precipitates and contaminants through diffraction pattern, X-ray and electron-energy analysis.
The word “transmission” means “to pass through”. The way the transmission electron
microscope creates a conventional image which is usually termed a bright field image of a
sample which can be compared to shadow puppetry. Imagine a torch beam shone through a
lattice on a window. The light passes through the transparent parts of the window, but is stopped
by the lattice bars. On a wall beyond, we see the lattice bars as shadows. The TEM uses a beam
of highly energetic electrons instead of light from a torch. On the way through the sample some
parts of the material stop or deflect electrons more than other parts. The electrons are collected
from below the sample onto a phosphorescent screen or through a camera. In the regions where
electrons do not pass through the sample the image is dark. Where electrons are unscattered,
the image is brighter, and there are a range of greys in between depending on the way the
electrons interact with and are scattered by the sample.
Operating Principles of the transmission electron microscope.
Ran to the electron beam collides with an object to be illuminated. By virtue of the power input
to the coil as cathode. When enough energy. Electrons are released. But because of the electron
as it befitted a terminal electron donor. It will run up to the electrodes charged particles in the
air as well. The electron cannot run into the target samples or sample in a microscope, so to
make a vacuum and there will be an increase in light intensity Condenser. Which uses a coil
wrapped around a rod. To induce the direction of the electron beam in the same
direction. Which the intensity of the electron increases.
When a particle or electron beam can be run against an object or workpiece. The beam of light
will be absorbed and the rest can be created through the object to the lens, the Objective Len
the bottom of the lens material and lens system to weed out. The two routes. The image is a
two-dimensional Fluorescence screen screens.
The TEM is a popular choice for nanotechnology as well as semiconductor analysis and
production. They require high voltages to increase the acceleration speed of electrons, which,
4. once they pass through the sample (transmission), increase the image resolution.
Magnifications of up to 1, 000,000x and resolution below 1 nm are achieved routinely which
can be used to quantitative and qualitative elemental analysis. A scale bar is essential on a TEM
image. From this the actual size of structures in the image can be calculated. For crystalline
phases the crystalline phases the crystal structure, lattice constraints and specimen orientation
can be determined. As we know that electron are negatively charged particles within the atom
therefore electromagnets are used to focus the electron unlike the light which can be focused
by the use of glass lenses.
Concepts related to TEM
The basis fundamental of electron microscopy is the use of an electron beam. It is for this
reason that the TEM requires a vacuum. If air were present the molecules would cause the
beam to scatter. It is also imperative to understand the interactions between the electron beam
and the sample so as to interpret the resulting images. The use of electrons has an impact on
image resolution and absence of colour, and explains the two dimensional nature of
micrographs
Resolution
Definitions
Resolution : It is the ability to distinguish closely spaced points as separate
points.
Resolution Limit : It is the smallest separation of points which can be recognized
as distinct.
Resolving Power : It can be stated as the resolution achieved by a particular
instrument under optimum viewing conditions.
Magnification
Magnification is simply the process of enlarging an image. Once a TEM is calibrated then it is
possible to determine exactly how much enlargement has occurred. This can be recorded on an
image as a scale bar. The use of ‘times magnification’, e.g. 50,000x, will only be accurate for
an image of set/ fixed dimension and so can lead to errors.
Higher magnification will not necessarily give higher resolution. Unless a microscope is
equipped to deliver higher resolution images, higher magnification will only achieve 'empty'
images.
5. Resolution in a microscope is determined primarily by the wave nature of light or electrons
according to Abbe's equation:
TEM resolution equation
d Resolution(minimum resolvable
distance)
λ wavelength of the energy source
n refractive index of the medium
α aperture angle
Note: The term nsinα is named numerical aperture.
Illumination with a smaller wavelength results in better resolution (the two spots can be seen
as distinct) and this is why the electron microscope produces higher resolution images than the
light microscope; because the wavelength of an electron is smaller than visible light.
TEM Generation theory
• Wavelength
• Image types
• Image formation basics
• Diffraction basics
6. • Diffraction images
• Combining images
• Imaging mode setup
• Focus/stigmation
The electron wavelength
The wavelength of an electron is dependent upon accelerating voltage and is given by:
Where
h Plank’s constant (6.626 x 10-34
J s)
m electron mass (9.109 x 10-31
kg)
e electronic charge (1.60 x 10-19
C)
V accelerating voltage (0.5 - 3 x 104
V)
The equation can be approximated to:
The higher the accelerating voltage, the smaller the wavelength of the electrons and the higher
the possible achievable resolution.
Image types
Bright field, HREM and diffraction images
The most common image generated is a bright field image by using a TEM. Some areas of the
sample scatter or absorb electrons and therefore they appear darker. Alternatively other areas
which transmit electrons appear brighter. In simple terms the bright field image appears as a
shadow of the specimen. In the bright field image the objective aperture is used to select the
unscattered electron beam. In doing so, the scattered electrons are excluded from forming the
image. This aperture enhances the contrast in the image.
Dark field images are produced by excluding, using the primary aperture, the primary
(unscattered) beam from the image collected below the sample. The image is produced by
scattered electrons (i.e. only selected electrons are used to form the image). Regions where no
scattering occurs, such as where the primary electron beam passes straight through the sample,
appear black (e.g. in areas around the sample). This kind of imaging is useful in studying crystal
defects, and for the imaging of specific crystallographic phases.
Diffraction images are the result of Bragg scattering as the beam passes through a crystalline
sample. If a “selected area diffraction aperture” is inserted to delimit the region of interest, then
an image created below the sample (in the region called the back focal plane) is seen as an
array of dots (or a set of diffuse rings). This informs the viewer about the crystal structure of
the sample.
7. Image formation basics
The TEM images are formed in two stages:
A)
Stage A is the scattering of an
incident electron beam by a
specimen. This scattered
radiation passes through an
objective lens, which focuses
it to form the primary image.
B)
Stage B uses the primary
image obtained in stage A and
magnifies this image using
additional lenses to form a
highly magnified final image.
8. In the process of forming the primary image the objective lens produces a diffraction pattern
at its back focal plane. The diffraction pattern is a Fourier transform of the scattered electron
wave. The primary image is the Fourier transform of the diffraction pattern.
This two-step process forms the basis of image formation during high-resolution transmission
electron microscopy (HRTEM).
The high-resolution image is, in effect, an interference pattern of the beams formed at the back
focal plane of the objective lens.
Diffraction basics
Samples viewed using the TEM can provide information
about its structure, in particular its crystalline nature.
This is because a crystal lattice acts as a diffraction
grating: interference patterns are produced in the
electron beam as it travels out from the lattice and these
can be projected as an image of regular dots or rings.
Image appearance
At high magnification, crystals may exhibit diffraction
contrast. This can occur for one of two reasons:
1. Strongly diffracting regions of crystals can
appear darker because there are fewer
electrons transmitted along the primary
beam. These crystals may be sitting on the
grid holder at a tilted angle so that a lattice of
the crystal lines up parallel to the beam.
2. Thicker regions can also appear darker due to
greater scattering. This can be seen in the image
here, where some crystals lie on top of one
another.
As the sample is tilted it will change in appearance to darker or lighter contrast depending on
how the beam is interacting with the internal lattice. When strong diffraction conditions are
achieved, the image will appear darker as more electrons are scattered outside of the objective
aperture.
9. The diffracted beam
When the electron beam passes through the
thin crystalline sample, it is diffracted by
the atomic planes in the sample when the
Bragg condition is satisfied. These waves
interact constructively and are brought to
focus at the back focal plane of the objective
lens (seePlanes) to form the diffraction
pattern.
Unscattered electrons continue through to O
to produce a central spot. The beam
diffracted by angle 2ΘB produces a spot,
marked G. The distance between a
diffracted (G) and transmitted (O) spot is
inversely proportional to the corresponding
lattice spacing in the sample.
The beam deflection angle and electron
beam wavelength are important.
Bragg's law describes the interaction:
λ = 2d sin ΘB
This equation can be used as long as the
wavelength is less than the crystal
interplanar spacing (d). This works for a
TEM where the accelerated electron beam
describes a wavelength of a few pm. This means for most crystalline materials that the Bragg
angle is much less than 1°.
The Camera length (projection distance) is also important to know in order to calculate details
about the sample. It can be set when photographing a diffraction pattern.
10. Tilting
The appearance of a diffraction pattern will depend
on the orientation of the specimen to the electron
beam. If the specimen is tilted so a plane of atoms or
crystallographic direction satisfies the Bragg
condition, distinctive diffraction patterns will be
obtained with diffraction maxima (i.e. spots - often
called reflections) in arrangements which reflect the
crystal structure of the specimen.
To achieve this, samples in a TEM can be tilted.
There are both single-tilt and double-tilt specimen
holders. A double-tilt holder is superior since the
tilting of the sample can be achieved in two axes (X
and Y). It is common to try and tilt a sample so that a
crystal zone axis is, in effect, parallel to the electron beam. Under these conditions a predictable
arrangement of reflections will be present in the diffraction pattern - see the pattern below for
ZnO.
Kikuchi Patterns
Bragg scattering, that is diffraction of inelastically scattered electrons, can lead to the formation
of pairs of parallel lines in the diffraction pattern called Kikuchi lines. For each plane of atoms
in the sample there exists a pair of parallel lines, rather like train lines. The various sets of
Kikuchi lines intersect in diffraction space in a manner which represents the arrangement of
crystal planes in real space. This is called a Kikuchi map. These lines can help an operator to
tilt a crystal around to find different crystal planes. Kikuchi Patterns are a useful phenomenon
to use when initially learning how to tilt crystals because they form regular intersecting lines
over a zone axis.
This spot diffraction pattern shows Kikuchi lines on the left side of the pattern. This pattern is
in the process of being tilted and not yet on the zone axis.
11. Diffraction patterns
The appearance of the diffraction pattern can reflect the nature of the crystalline phases in the
specimen. For example, if the material is microcrystalline or amorphous the diffraction pattern
consists of a series of concentric rings rather than spots/discs.
Spot patterns
When the electron beam interacts with the sample
when the sample is oriented with a zone axis pattern
parallel to the electron beam, then the diffraction
pattern form in the back focal plane of the objective
lenses a regular array of reflections. This is seen
projected onto the viewing screen as an array of
reflections organized in a predictable manner based
on the crystal structure of the sample.
12. Convergent Beam Electron Diffraction (CBED)
When the electron beam is converged on the sample to a
point (method = convergent beam), instead of using a parallel
stream of electrons through the sample, the diffraction pattern
forms discs instead of spots in the back focal plane of the
objective lens.
These discs can contain detail that provides information about
the crystal structure of the specimen. In these images we see
almost perfect mirror symmetry in the patterns within the
discs. These symmetries can be used to determine the ponit
and space group of the crystal.
Ring patterns
Sometimes, instead of intensity spots, the electron diffraction
pattern is composed of concentric rings.
Materials that contain no long-range order in the atomic lattice
produce diffuse ring diffraction patterns with no discrete
reflections and one or possibly two diffuse rings of maximum
intensity. Amorphous samples, e.g. polymers and metallic
glasses, produce this kind of pattern.
The bar across the pattern is the “beam stop” used to cover
the bright central beam spot so that the more diffuse rings can
be captured as a digital image.
If the material is a collection of a large number of crystals,
with different orientations, then individual reflections are
seen within the rings
.
Combining images
Images can be combined to get the most information out of a sample.
13. The diffraction pattern is a mixture of information from closely positioned crystals that are all
fairly similarly aligned so the patterns are being gained from three of the crystals at the same
time.
In one sense it is not an ideal diffraction pattern because it contains multiple sets of information.
When tem is used?
A Transmission Electron Microscope (TEM) is used when morphologic, compositional and
crystallographic information of samples needs to be found out and also when high resolving
power is needed, it enables to characterize the microstructure as well as the crystal structure of
the area. By using a TEM we can see the columns of atoms present in crystalline samples.
Quantitative and qualitative elemental analysis can be provided from feature as small as 1nm
with the magnification of up to 1,000,000x and for crystal structure lattice constraints and
specimen orientation can be determined by the use of TEM. The operation of the microscope
can be can be divided to three categories i.e. bright field image, dark field image and saed. The
dark field image helps in identifying the specific features and generally have better clarity and
resolution as these results from a specific diffracted beam. Bright image may be taken while
the diffraction pattern correspondences to a two- beam condition needed, for defect analysis or
multi beam condition to arrive at orientation relationship among the phases and
crystallographic planes and direction corresponding to specific microstructure features, the
sample required for tem is very thin≈≈100nm. The image can be recorded on the 35mm or a
plate camera.
14. TEM components
An electron source (electron gun)
Thermionic Gun
Electron beam
Electromagnetic lenses
Vacuum chamber
Chilling system
Sample/Specimen stage
Phosphor or fluorescent screen (Image capture)
Main control panel and operational control
Benefits of using TEM
A Transmission Electron Microscope is an impressive instrument with a number of advantages
such as:
TEMs offer the most powerful magnification, potentially over one million times or
more
TEMs have a wide-range of applications and can be utilized in a variety of different
scientific, educational and industrial fields
TEMs provide information on element and compound structure
Images are high-quality and detailed
TEMs are able to yield information of surface features, shape, size and structure
They are easy to operate with proper training
The transmission electron microscope (TEM) provides the user with advantages over the
microscope in three key areas:
Resolution at high magnification. Resolution can be defined as the smallest distance
between two closely opposed points, at which they may be recognized as two separate
entities. A typical TEM has a resolution of better than 1 nm.
Structural information. If the material being viewed has a periodic structure like a
crystal then the beam can interact with that structure in such a way that it diffracts. This
provides information on crystal structure, symmetry and orientation of materials.
Microanalysis i.e. the analysis of sample chemical composition can be performed in the
TEM.
15. Application
TEMs have a wide-range of applications in a variety of scientific, education, research and
industrial fields. The Transmission Electron Microscopes has practical applications in such
fields as chemistry, gemology, metallurgy, industry and nanotechnologies as well as provide
information on the topography, morphology, composition and crystallographic data of
samples. TEMs also have many technological and industrial applications, such as
semiconductor inspection, computer chip manufacturing, quality control and can even be used
as part of a production line. The images allow researchers to view samples on a molecular level,
making it possible to analyse structure and texture. Analysis often includes Defect analysis,
failure analysis, materials qualification, electron tomography, structural biology, virology,
forensics, structural composition, chemical composition, steels, aluminium alloys, ceramics
and semiconductor devices. Technology companies use TEMs to identify flaws, fractures and
damages to micro-sized objects; this data can help fix problems and/or help to make a more
durable, efficient product. It also enables the investigation of crystal structures, orientations
and chemical compositions of phases, precipitates and contaminants through diffraction
pattern, characteristic X-ray, and electron energy loss analysis.
Transmission electron microscopy can:
Image morphology of samples, e.g. view sections of material, fine powders suspended
on a thin film, small whole organisms such as viruses or bacteria, and frozen solutions.
Tilt a sample and collect a series of images to construct a 3-dimensional image.
Analyse the composition and some bonding differences (through contrast and by using
spectroscopy techniques: microanalysis and electron energy loss).
Physically manipulate samples while viewing them, such as indent or compress them
to measure mechanical properties (only when holders specialised for these techniques
are available).
View frozen material (in a TEM with a cryostage).
Generate characteristic X-rays from samples for microanalysis.
Acquire electron diffraction patterns (using the physics of Bragg Diffraction).
Perform electron energy loss spectroscopy of the beam passing through a sample to
determine sample composition or the bonding states of atoms in the sample.
16. What is nanotechnology?
The design, characterization, production, and application of structures, devices, and systems
by controlled manipulation of size and shape at the nanometer scale (atomic, molecular, and
macromolecular scale) that produces structures, devices, and systems with at least one
novel/superior characteristic or property.
There are many different views of precisely what is included in nanotechnology. In general,
however, most agree that three things are important:
1. Small size, measured in 100s of nanometers or less
2. Unique properties because of the small size
3. Control the structure and composition on the nm scale in order to control the properties.
Nanostructures—objects with nanometer scale features
So how TEM as a versatile tool for research in Nanotechnology?
As we have come to understand that nanotechnology includes structures having unique
property with small size measured in 100s of nanometer or less therefore for the analysis of
Defect, failure analysis, materials qualification, electron tomography, structural biology,
virology, forensics, structural composition, chemical composition and semiconductor devices
TEM plays an important role. As Transmission Electron Microscope (TEM) is used when
morphologic, compositional and crystallographic information of samples needs to be found out
and also when high resolving power is needed, it enables to characterize the microstructure as
well as the crystal structure of the area. By using a TEM we can see the columns of atoms
present in crystalline samples. Quantitative and qualitative elemental analysis can be provided
from feature as small as 1nm with the magnification of up to 1,000,000x and for crystal
structure lattice constraints and specimen orientation can be determined by the use of TEM.
The operation of the microscope can be can be divided to three categories i.e. bright field
image, dark field image and saed. The dark field image helps in identifying the specific features
and generally have better clarity and resolution as these results from a specific diffracted beam.
Bright image may be taken while the diffraction pattern correspondences to a two- beam
condition needed, for defect analysis or multi beam condition to arrive at orientation
relationship among the phases and crystallographic planes and direction corresponding to
specific microstructure features.
17. How can a TEM be used to study defect
Transmission electron microscopy (TEM) is till now the most important technique
for studying defects in great detail. Much of what was stated before about defects
would be speculative theory, or would never have been conceived without TEM.
High-Resolution TEM (HRTEM) is the ultimate tool in imaging defects. In favourable cases it
shows directly a two-dimensional projection of the crystal with defects and all.
Some special contrast features arises due to Two-dimensional defects like stacking faults, and
also by grain- and phase boundaries to some extent. Stacking faults are best seen and identified
under dynamical two-beam condition; i.e. the Bragg condition is exactly met for one point in
the reciprocal lattice. This implies that if the diffracted beam is seen as the primary beam, also
meets the Bragg condition; it is diffracted back into the primary beam wave field. This leads to
an oscillation of the intensity between the primary and the diffracted beam as a function of
depth in the sample; the "wave length" of this periodic intensity variations is called the
extinction length ξ.
Technology companies use TEMs to identify flaws, fractures and damages to micro-sized
objects; this data can help fix problems and/or help to make a more durable, efficient product.
TEM image simulations
Every image detail, or contrast, appearing on the phosphorescent screen of a transmission
electron microscope (TEM) is the result of the interaction of the electron beam with the sample.
Unlike the direct interpretation we can give of the eye visible world, the interpretation of TEM
micrographs is far from straightforward and has to be considered carefully. The origins of the
TEM contrasts are complex and multiple. They are divided here into the following four
categories:
1. Absorption contrast,
2. Structure contrast,
3. Diffraction contrast,
4. Phase contrast.
The contrast formation theories, even though based on sometimes tricky approximations, give
a good description of the TEM images. With the help of these theories, the TEM images can
be reproduced by large numerical calculations. The image simulation appears as a powerful
tool for the identification of an object at the origin of an observed contrast.
18. Samples can exhibit diffraction contrast, whereby the electron beam undergoes Bragg
scattering, which in the case of a crystalline sample, disperses electrons into discrete locations
in the back focal plane. By the placement of apertures in the back focal plane, i.e. the objective
aperture, the desired Bragg reflections can be selected (or excluded), thus only parts of the
sample that are causing the electrons to scatter to the selected reflections will end up projected
onto the imaging apparatus. Applications for this method include the identification of lattice
defects in crystals.
Crystal structure can also be investigated by high-resolution transmission electron microscopy
(HRTEM), also known as phase contrast. When utilizing a Field emission source and a
specimen of uniform thickness, the images are formed due to differences in phase of electron
waves, which is caused by specimen interaction
Contrast in Imperfect Crystals – Defect Imaging
For getting best diffraction contrast from defects it is advisory for the specimen to be tilted so
that we have two-beam condition with slight deviation from the Bragg conditions. This is
measured by the vector s (K=g+s, where K is diffraction vector and g is reciprocal lattice
vector), which is called the excitation error or deviation parameter.
If the excess Kikuchi line lies outside its corresponding diffraction spot g, we say that s>0.
Alternatively if the excess Kikuchi line lies inside it corresponding diffraction spot g we say
that s<0 and we say that s=0 when the Kikuchi line runs through its corresponding spot g
exactly as it can be seen from Fig. The best possible strong-beam image contrast conditions is
small and positive deviation parameter s for a defect imaging.
19. Dislocation Imaging
For understanding why contrast from dislocation is observed, one should understand the
schematic diagram in Fig. If the diffraction geometry is set slightly away from the Bragg
conditions, the distortion due to the dislocation will then bend the near-diffracting planes back
into the Bragg-diffracting conditions. So, regions either sides of the dislocation core are at the
Bragg condition for ±ghkl, while the regions far from the dislocation are tilted well away from
the Bragg condition.
Important information which needs to be extracted from TEM images regarding dislocations
are:
1) The direction and the magnitude of the Burgers vector, b, which is normal to the hkl
diffracting planes;
2) The direction of line (a vector) and also the character of the dislocation (edge, screw,
or mixed);
3) The glide plane;
4) The density of the dislocations;
20. 5) If the dislocations are interacting with other each another or other defects.
A general rule that can be used to determine the Burgers vector is the called “g.b rule”, which
states that if the Burgers vector of the dislocation is perpendicular to the active diffraction
vector, i.e. g.b=0, there is absence of diffraction contrast from the dislocation. The dislocation
is invisible. This is well illustrated by Fig.
21.
22. Stacking Faults Imaging
An error in the stacking sequence exists when two adjacent atomic planes are not in their proper
crystallographic position. Atoms across a stacking fault are shifted of their proper positions by
a displacement equal to the Burgers vector of a partial dislocation. A stacking fault can be quite
wide even though it is only one atomic thick plane in thickness which often extends fully across
a crystal. The TEM image of a stacking fault is generally a set of fringes which run parallel to
the intersection of the fault with the surfaces of the specimen. Such an image of stacking faults
is shown in Fig.
The least complicated of the planar defects is the stacking fault since only a displacement of
the crystal across the fault plane is involved. A phase change α=2πg.R (R is the displacement
vector) is observed when a wave crosses a faulted region of a crystal. Since α is a phase factor,
everything is unaffected under changes of 2π.
23. The dependency of the intensity of the fringes on the sign of α is predicted by dynamical theory.
For α positive the first fringe is light, whereas for α negative the first fringe is dark, in bright
field. The reverse is true for dark field images which is for α positive the first fringe is dark,
whereas for α negative the first fringe is light. This rule can be used to determine whether a
fault or thin slab of substrate is intrinsic or extrinsic, but it is necessary to know the sense of
slope of the fault plane with respect to g. Since an extrinsic fault is considered of as one because
of insertion of an extra pane of atoms, and an intrinsic fault as one formed by removal of a
plane, the sign of R will be opposite for intrinsic and extrinsic faults, and hence the sign of
α=2πg.R will be reversed for these cases when the same g operates. The nature of the fault can
be determine by observing the color of the first fringe, one may discover whether β is acute or
obtuse if we consider the top half of the crystal to be fixed and the bottom half displaced by
the fault displacement vector R as shown in Fig, and knowing the direction of g. The rules for
determination for face centered cubic crystals are summarized in Fig.
24. We may draw the following conclusions
They are justified by the full theory of TEM contrast.
• Dislocations are invisible or exhibit only weak contrast if g • b = 0. This can be used
for a Burgers vector analysis by imaging the same dislocation with different diffraction
vectors and observing the contrast.
• Under kinematic bright field conditions (Bragg condition met almost, but not quite),
the dislocation is imaged as a dark line on a bright background. The width of the line
corresponds to the width of the region next to one side of the dislocation where the
Bragg condition is now met; which is usually several nm.
• Under dark field conditions the dislocation appears bright on a dark background.
• Under dark field conditions with large excitation errors the Bragg condition is only met
in a small region close to the core of the dislocation. The image consists of a thin white
line on a pitch black background. This is the so-called "weak-beam" condition; it has
the highest resolution of conventional imaging modes. It is hard to use, however,
because almost nothing is seen on the screen (making adjustments difficult) and long
exposure times are needed which are only practical with a very stable instrument.
25. References
1. Abramowitz M, Davidson MW (2007). "Introduction to Microscopy". Molecular
Expressions. Retrieved 2007-08-22.
2. Abramowitz M, Davidson MW (2003-08-01). "Darkfield Illumination". Retrieved
2008-10-21.
3. Fultz, B and Howe, J (2007). Transmission Electron Microscopy and Diffractometry
of Materials. Springer. ISBN 3-540-73885-1.
4. Champness, P. E. (2001). Electron Diffraction in the Transmission Electron
Microscope. Garland Science. ISBN 1-85996-147-9. ISSN 978-1859961476.
5. Hubbard, A (1995). The Handbook of surface imaging and visualization. CRC Press.
ISBN 0-8493-8911-9.
6. Williams, D and Carter, C. B. (1996). Transmission Electron Microscopy. 1 – Basics.
Plenum Press. ISBN 0-306-45324-X.
7. Cowley, J. M (1995). Diffraction physics. Elsevier Science B. V. ISBN 0-444-82218-
6.
8. Michael A. O’Keefe and Lawrence F. Allard. "Sub-Ångstrom Electron Microscopy
for Sub-Ångstrom Nano-Metrology". National Nanotechnology Initiative Workshop
on Instrumentation and Metrology for Nanotechnology, Gaithersburg, MD (2004).
9. Transmission Electron Microscopy, D.B.Williams and C.B.Carter, Plenum Press,
New York, 1996.
10. Transmission Electron Microscopy and Diffractometry of Materials, B.Fultz and J.M.
Howe, Springer-Verlag Berlin Heidelberg New York 2001.
11. Transmission Electron Microscopy and Diffractometry of Materials, B.Fultz and J.M.
Howe, Springer-Verlag Berlin Heidelberg New York 2001.
12. Electron Beam Analysis of Materials, M.H. Loretto, Chapman and Hall, London New
York 1984.
13. http://www-hrem.msm.cam.ac.uk/research/EFTEM/EFTEM.html
14. http://www.microscopy.ethz.ch/
15. www.matter.org.uk
16. Wikipedia
17. Science direct
18. Clustered data collected from Internet and banner at lab.