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ELECTRON MICROSCOPY
Electron Microscopes are scientific instruments that use a beam of highly energetic electrons
to examine objects on a very fine scale.
Provide information of topography, morphology, composition and crystallographic
information.
Electron Microscopes were developed due to the limitations of Light Microscopes which are
limited by 500x or 1000x magnification and a resolution of 0.2 micrometers.
Types of EM’s- Transmission Electron Microscope (TEM)
Scanning Electron Microscope (SEM)
INTRODUCTION
The first type of Electron Microscope developed was Transmission Electron Microscope.
It was developed by Max Knoll and Ernst Ruska in Germany in 1931.
The first Scanning Electron Microscope (SEM) debuted in 1942 with the first commercial
instruments around 1965.
Electron Microscopy
LIGHT MICROSCOPE Vs TEM and SEM
Electron Microscopes (EMs) function exactly as their optical counterparts except that they use
a focused beam of electrons instead of light to "image" the specimen and gain information as
to its structure and composition.
The basic steps involved in all Ems are the following: A stream of electrons is formed in high
vacuum (by electron guns). This stream is confined and focused using metal apertures and
magnetic lenses into a thin, focused, monochromatic beam and is accelerated towards the
specimen (with a positive electrical potential). The sample is irradiated by the beam and
interactions occur inside the irradiated sample, affecting the electron beam. These
interactions and effects are detected and transformed into an image.
In the electron microscope, the light source is replaced by an electron source, the glass
lenses are replaced by magnetic lenses, and the projection screen is replaced by a
fluorescent screen, which emits light when struck by electrons, or, more frequently in
modern instruments, an electronic imaging device such as a CCD (charge-coupled device)
camera.
The whole trajectory from source to screen is under vacuum and the specimen (object) has
to be very thin to allow the electrons to travel through it.
TRANSMISSION ELECTRON MICROSCOPE (TEM):
There are four main components to a transmission electron microscope: an electron optical
column, a vacuum system, the necessary electronics (lens supplies for focusing and
deflecting the beam and the high voltage generator for the electron source), and control
software.
The light source of the light microscope is replaced by an electron gun, which is built into the
column. The electron beam emerges from the electron gun (usually at the top of the column),
and is condensed into a nearly parallel beam at the specimen by the condenser lenses.
The specimen must be thin enough to transmit the electrons, typically 0.5 μm or less.
After passing through the specimen, transmitted electrons are collected and focused by the
objective lens and a magnified real image of the specimen is projected by the projection
lens(es) onto the viewing device at the bottom of the column.
The entire electron path from gun to camera must be under vacuum (otherwise the electrons
would collide with air molecules and be scattered or absorbed).
Working concept of TEM
COMPONENTS OF THE TEM:
• Source – filament plus anode plates with applied accelerating voltage.
• Condenser Lenses – electromagnetic lenses adjusted by lens currents not position.
• Specimen Stage – allows translations and tilts.
• Objective Lens – usually <50X.
• Imaging System – multiple electromagnetic lenses below the objective: set
magnification, focal plane (image vs. diffraction pattern).
• Observation – fluorescent screen, plate film, CCD camera.
ELECTRON GUN:
The first and basic part of the microscopes is the source of electrons.
It is usually a V-shaped filament made of LaB6 or W (tungsten) that is wreathed with Wehnelt
electrode (Wehnelt Cap).
Types of electron guns: Thermionic Electron Guns and Field Emission Guns (FEG).
In conventional thermionic electron gun, a positive electrical potential is applied to the
anode, and the filament (cathode) is heated until a stream of electrons is produced. The
electrons are accelerated by the positive potential down the column, and because of the
negative potential of cap, all electrons are repelled toward the optic axis.
A collection of electrons occurs in the space between the filament tip and Cap, which is called
a space charge. Those electrons at the bottom of the space charge which are nearest to the
anode can exit the gun area through the small (<1 mm) hole in the Wehnelt Cap and then
move down the column.
Electron Microscopy
If the application demands imaging at magnifications up to 40-50 kX in TEM mode, a
tungsten source is the best source for the application. When the TEM imaging magnification is
between 50-100 kX, then LaB6 source. If magnifications higher than 100 kX are required, a
field emission source gives the better signal.
 A field emission gun consists of a sharply pointed tungsten tip held at several kilovolts
negative potential relative to a nearby electrode, so that there is a very high potential
gradient at the surface of the tungsten tip. As a result, potential energy of an electron as a
function of distance from the metal surface has a sharp peak, then drops off quickly (due to
electron charge traveling through an electric field). This transport-via-delocalization is
called 'tunneling', and is the basis for the field emission effect.
FEGs produce much higher source brightness than in conventional guns (electron current >
1000 times), better monochromaticity, but requires a very good vacuum (~10-7 Pa).
ELECTRON-SPECIMEN INTERACTIONS
When an electron beam interacts with the atoms in a sample, individual incident electrons
undergo two types of scattering - elastic and inelastic.
Elastic- Only the trajectory changes and the kinetic energy and velocity remain constant.
Inelastic- Some incident electrons will actually collide with and displace electrons from their
orbits (shells) around nuclei of atoms comprising the sample. This interaction places the atom
in an excited (unstable) state.
Specimen interaction is what makes Electron
Microscopy possible.
The inelastic interactions are utilized when
examining thick or bulk specimens (SEM).
On the bottom side are those examined in thin or
foil specimens (TEM).
Reactions Exploited In TEM:
TEM exploits three different interactions of electron beam-specimen;
unscattered electrons (transmitted beam)
elastically scattered electrons (diffracted beam)
inelastically scattered electrons
When incident electrons are transmitted through the thin specimen without any interaction
occurring inside the specimen, then the beam of these electrons is called transmitted.
The transmission of unscattered electrons is inversely proportional to the specimen thickness.
Areas of the specimen that are thicker will have fewer transmitted electrons and so will appear
darker, conversely the thinner areas will have more transmitted and thus will appear lighter.
Another part of the incident electrons, are scattered (deflected from their original path) by
atoms in the specimen in an elastic fashion (no loss of energy).
These scattered electrons are then transmitted through the remaining portions of the specimen.
All electrons follow Bragg's Law and thus are scattered according to
nλ = 2d sinθ
where:
λ is the wavelength of the rays
θ is the angle between the incident rays and the surface of the crystal and
d is the spacing between layers of atoms.
All incidents that are scattered by the same atomic spacing will be scattered by the same angle.
These scattered electrons can be collated using magnetic lenses to form a pattern of spots; each
spot corresponding to a specific atomic spacing (a plane). This pattern can then yield
information about the orientation, atomic arrangements and phases present in the area being
examined.
Finally, another way that incident electrons can interact with the specimen is inelastically.
These electrons are then transmitted through the rest of the specimen. Inelastically scattered
electrons can be utilized in two ways; Electron Energy Loss Spectroscopy (EELS) and Kikuchi
Bands.
The electromagnetic lenses:
When an electric current is passed through the coils (C), an electromagnetic field is created
between the pole pieces (P), which forms a gap in the magnetic circuit. By varying the
current through the coils, the strength of the field, and thereby the power of the lens, can be
varied.
This is the essential difference between the magnetic lens and the glass lens. Otherwise they
behave similarly and have the same types of aberration:
Spherical aberration (Cs – the power in
the center of the lens differs from that at the edges),
Chromatic aberration (Cc – the power of the lens
Varies with the energy of the electrons in the beam), and
Astigmatism (a circle in the specimen becomes an
ellipse in the image).
In a conventional TEM, spherical aberration, which is
largely determined by the lens design and manufacture,
is the primary limitation to improved image resolution.
Chromatic aberration can be reduced by keeping the
accelerating voltage as stable as possible and using
very thin specimens. Astigmatism can be corrected
by using variable electromagnetic compensation coils.
The condenser lens system focuses the electron beam onto the specimen under investigation.
The objective lens produces an image of the specimen which is then magnified by the
remaining imaging lenses and projected onto the viewing device.
The objective lens is followed by several projection lenses used to focus, magnify, and
project the image or diffraction pattern onto the viewing device.
On the way from the source to the viewing device, the electron beam passes through a series
of apertures with different diameters. These apertures stop those electrons that are not required
for image formation (e.g., scattered electrons). Using a special holder carrying a number of
different size apertures, the diameter of the apertures in the condenser lens, the objective lens,
and the diffraction lens can be changed as required.
Specimen orientation and manipulation:
The TEM specimen stage must provide various movements to manipulate and orient the
sample. X, Y, and Z translation, and tilt are used to move the appropriate region of the sample
into the field of view of the microscope.
The basic movements are provided by a goniometer mounted very close to the objective lens.
Specimen preparation:
A TEM can be used in any branch of science and technology where it is desired to study the
internal structure of specimens down to the atomic level. Different thicknesses are required
for different applications. For the ultimate high resolution materials studies, the sample cannot
be thicker than 20 nm or so; for bio-research, the film can be 300-500 nm thick.
In biology, for example, there may be first a chemical treatment to remove water and preserve
the tissue as much as possible in its original state, followed by embedding in a hardening
resin; after the resin has hardened, slices (sections) with an average thickness of 0.5 μm are
cut with an instrument called an ultramicrotome equipped with a glass or diamond knife. The
tiny sections thus obtained are placed on a specimen carrier – usually a 3 mm diameter copper
specimen grid that has been coated with a structure less carbon film 0.1 μm thick.
Cryo (freezing) techniques avoid the sample damage unavoidably caused by conventional
drying, fixing, and sectioning preparations.
Observing and recording the image:
Originally, TEMs used a fluorescent screen, which emitted light when impacted by the
transmitted electrons, for real-time imaging and adjustments; and a film camera to record
permanent, high resolution images. The screen was under vacuum in the projection chamber,
but could be observed through a window, using a binocular magnifier if needed. The
fluorescent screen usually hinged up to allow the image to be projected on the film below.
Modern instruments rely primarily on solid-state imaging devices, such as a CCD (charge-
coupled device) camera, for image capture. They may still include a fluorescent screen, but it
may be observed by a video camera. In this text, unless we are discussing specific aspects of
the imaging system, we will simply refer to an imaging device.
The recent introduction of a direct electron detector promises significant improvements in
image resolution and contrast, particularly in signal-limited applications. A conventional CCD
camera uses a scintillator material over the image detector elements to convert incident
electrons to light, which then creates charge in the underlying CCD element. The scintillator
introduces some loss of resolution and the conversion process decreases the efficiency with
which electrons contribute to image contrast. Eliminating the scintillator with a direct electron
detector improves image resolution and increases detector efficiency by up to three times.
A scanning electron microscope, like a TEM, consists of an electron optical column, a vacuum
system, electronics, and software.
The column is considerably shorter because the only lenses needed are those above the
specimen used to focus the electrons into a fine spot on the specimen surface. There are no
lenses below the specimen.
The specimen chamber, on the other hand, is larger because the SEM technique does not
impose any restriction on specimen size other than that set by the size of the specimen
chamber.
SCANNING ELECTRON MICROSCOPE (SEM)
The electron gun at the top of the column produces an electron beam that is focused into a fine
spot as small as 1 nm in diameter on the specimen surface. This beam is scanned in a
rectangular raster over the specimen and the intensities of various signals created by
interactions between the beam electrons and the specimen are measured and stored in
computer memory.
The secondary electron (SE) signal is the most frequently used signal.
Components of SEM:
• Produce a stream of monochromatic electrons in the electron gun.
• Focus the stream using the first condenser lens
• The beam is constricted by the condenser aperture (eliminates high-angle electrons).
• Second condenser lens is used to form electrons into a thin, tight, coherent beam.
• Use objective aperture to limit beam (i.e., eliminate high-angle electrons)
• Scan coils raster the beam across the sample, dwelling on the points for a
predetermined period of time (selected using scan speed)
• Final objective lens focuses beam on desired region.
• When beam strikes the sample, interactions occur.
We detect what comes out of the sample.
SEM: Technical Details:
The electron gun and lenses are similar to those
described previously for TEM.
The most important differences between TEM
and SEM are:
• Rather than the broad static beam used in
TEM, the SEM beam is focused to a fine point
and scanned line by line over the sample
surface in a rectangular raster pattern.
• The accelerating voltages are much lower
than in TEM because it is no longer necessary
to penetrate the specimen; in a SEM they range
from 50 to 30,000 volts.
• The specimen need not be thin, greatly
simplifying specimen preparation.
INTERACTIONS OBSERVED IN SEM:
Backscattered electrons (BSE)
• Formation
– Caused when incident electrons collide
with an atom in a specimen that is nearly
normal to the path of the incident beam.
– Incident electron is scattered backward
(“reflected”).
• Use
– Production varies with atomic number (Z).
– Higher Z elements appear brighter than
lower Z elements.
– Differentiate parts of specimen having
different atomic number
Secondary Electrons (SE)
• Formation
– Caused when an incident electron “knocks”
and inner shell electron (e.g., k-shell) out of its
site.
– This causes a slight energy loss and path
change in the incident electron and ionization
of the electron in the specimen.
– The ionized electron leaves the atom with a
small kinetic energy (~5 eV).
• Use
– Production is related to topography. Due to
low energy, only SE near the surface can exit
the sample.
– Any change in topography that is larger than
the sampling depth will change the yield of SE.
Secondary electrons are more abundant than other types of electrons
Auger Electrons (AE):
• Formation
– De-energization of the atom after a
secondary electron is produced.
– During SE production, an inner shell
electron is emitted from the atom leaving a
vacancy.
– Higher energy electrons from the same
atom can fall into the lower energy hole.
This creates an energy surplus in the atom
which is corrected by emission of an outer
shell (low energy) electron.
• Use
– AE have characteristic energies that are
unique to each element from which they are
emitted.
– Collect and sort AE according to energy to
determine composition.
– AE have very low energy and are emitted
from near surface regions.
X-rays:
• Formation
– Same as AE. Difference is that the electron
that fills the inner shell emits energy to
balance the total energy of the atom.
• Use
– X-rays will have characteristic energies that
are unique to the element(s) from which it
originated.
– Collect and sort signals according to energy
to yield compositional information.
– Energy Dispersive X-ray Spectroscopy
(EDS)
The interactions between the beam electrons and sample atoms are similar to those described
for TEM:
• The specimen itself emits secondary electrons.
• Some of the primary electrons are reflected backscattered electrons (BSE). These
backscattered electrons can also cause the emission of secondary electrons as they
travel through the sample and exit the sample surface.
All these phenomena are interrelated and all of them depend to some extent on the
topography, the atomic number and the chemical state of the specimen. The most commonly
imaged signals in SEM are SE and BSE.
Relaxation of excited atoms
Inelastic scattering places the atom in an excited (unstable) state. The atom “wants” to return
to a ground or unexcited state. Therefore, at a later time the atoms will relax giving off the
excess energy. X-Rays, cathodoluminescence and Auger electrons are three ways of
relaxation. The relaxation energy is the fingerprint of each element.
Secondary and backscattered electrons are conventionally separated according to their
energies.
When the energy of the emitted electron is less than 50eV, it is referred as a secondary
electron and backscattered electrons are considered to be the electrons that exit the specimen
with an energy greater than 50eV.
Detectors of each type of electrons are placed in the microscope in proper positions to collect
them.
Electron detection:
Detectors for backscattered electrons and secondary electrons are usually either a scintillation
detector or a solid-state detector.
In the scintillator case, electrons strike a fluorescent screen, which emits light, that is amplified
and converted into an electrical signal by a photomultiplier tube. The solid-state detector works
by amplifying the minute signal produced by the incoming electrons in a semiconductor device.
Specimen preparation:
A SEM can be used whenever information is required about the surface or near-surface region
of a specimen. It finds application in almost every branch of science, technology, and industry.
The only requirement is that the specimen must be able to withstand the vacuum of the chamber
and bombardment by the electron beam.
If the specimen contains any volatile components such as water, they must be removed by a
drying process (or in some circumstances it can be frozen solid) before they can be used in a
high vacuum system.
Non-conducting specimens will accumulate charge under electron bombardment and may need
to be coated with a conducting layer. Iridium gives a fine grained coating and is easily applied
in a sputter coater. It gives a good yield of secondary electrons, and consequently, a good
quality image of the surface.
Cryo preparations are also used in SEM, particularly in biological applications or organic
materials (polymers).
Electron Microscopy
TEM SEM
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Electron Microscopy

  • 2. Electron Microscopes are scientific instruments that use a beam of highly energetic electrons to examine objects on a very fine scale. Provide information of topography, morphology, composition and crystallographic information. Electron Microscopes were developed due to the limitations of Light Microscopes which are limited by 500x or 1000x magnification and a resolution of 0.2 micrometers. Types of EM’s- Transmission Electron Microscope (TEM) Scanning Electron Microscope (SEM) INTRODUCTION The first type of Electron Microscope developed was Transmission Electron Microscope. It was developed by Max Knoll and Ernst Ruska in Germany in 1931. The first Scanning Electron Microscope (SEM) debuted in 1942 with the first commercial instruments around 1965.
  • 4. LIGHT MICROSCOPE Vs TEM and SEM
  • 5. Electron Microscopes (EMs) function exactly as their optical counterparts except that they use a focused beam of electrons instead of light to "image" the specimen and gain information as to its structure and composition. The basic steps involved in all Ems are the following: A stream of electrons is formed in high vacuum (by electron guns). This stream is confined and focused using metal apertures and magnetic lenses into a thin, focused, monochromatic beam and is accelerated towards the specimen (with a positive electrical potential). The sample is irradiated by the beam and interactions occur inside the irradiated sample, affecting the electron beam. These interactions and effects are detected and transformed into an image. In the electron microscope, the light source is replaced by an electron source, the glass lenses are replaced by magnetic lenses, and the projection screen is replaced by a fluorescent screen, which emits light when struck by electrons, or, more frequently in modern instruments, an electronic imaging device such as a CCD (charge-coupled device) camera. The whole trajectory from source to screen is under vacuum and the specimen (object) has to be very thin to allow the electrons to travel through it.
  • 6. TRANSMISSION ELECTRON MICROSCOPE (TEM): There are four main components to a transmission electron microscope: an electron optical column, a vacuum system, the necessary electronics (lens supplies for focusing and deflecting the beam and the high voltage generator for the electron source), and control software. The light source of the light microscope is replaced by an electron gun, which is built into the column. The electron beam emerges from the electron gun (usually at the top of the column), and is condensed into a nearly parallel beam at the specimen by the condenser lenses. The specimen must be thin enough to transmit the electrons, typically 0.5 μm or less. After passing through the specimen, transmitted electrons are collected and focused by the objective lens and a magnified real image of the specimen is projected by the projection lens(es) onto the viewing device at the bottom of the column. The entire electron path from gun to camera must be under vacuum (otherwise the electrons would collide with air molecules and be scattered or absorbed).
  • 8. COMPONENTS OF THE TEM: • Source – filament plus anode plates with applied accelerating voltage. • Condenser Lenses – electromagnetic lenses adjusted by lens currents not position. • Specimen Stage – allows translations and tilts. • Objective Lens – usually <50X. • Imaging System – multiple electromagnetic lenses below the objective: set magnification, focal plane (image vs. diffraction pattern). • Observation – fluorescent screen, plate film, CCD camera.
  • 9. ELECTRON GUN: The first and basic part of the microscopes is the source of electrons. It is usually a V-shaped filament made of LaB6 or W (tungsten) that is wreathed with Wehnelt electrode (Wehnelt Cap). Types of electron guns: Thermionic Electron Guns and Field Emission Guns (FEG). In conventional thermionic electron gun, a positive electrical potential is applied to the anode, and the filament (cathode) is heated until a stream of electrons is produced. The electrons are accelerated by the positive potential down the column, and because of the negative potential of cap, all electrons are repelled toward the optic axis. A collection of electrons occurs in the space between the filament tip and Cap, which is called a space charge. Those electrons at the bottom of the space charge which are nearest to the anode can exit the gun area through the small (<1 mm) hole in the Wehnelt Cap and then move down the column.
  • 11. If the application demands imaging at magnifications up to 40-50 kX in TEM mode, a tungsten source is the best source for the application. When the TEM imaging magnification is between 50-100 kX, then LaB6 source. If magnifications higher than 100 kX are required, a field emission source gives the better signal.  A field emission gun consists of a sharply pointed tungsten tip held at several kilovolts negative potential relative to a nearby electrode, so that there is a very high potential gradient at the surface of the tungsten tip. As a result, potential energy of an electron as a function of distance from the metal surface has a sharp peak, then drops off quickly (due to electron charge traveling through an electric field). This transport-via-delocalization is called 'tunneling', and is the basis for the field emission effect. FEGs produce much higher source brightness than in conventional guns (electron current > 1000 times), better monochromaticity, but requires a very good vacuum (~10-7 Pa).
  • 12. ELECTRON-SPECIMEN INTERACTIONS When an electron beam interacts with the atoms in a sample, individual incident electrons undergo two types of scattering - elastic and inelastic. Elastic- Only the trajectory changes and the kinetic energy and velocity remain constant. Inelastic- Some incident electrons will actually collide with and displace electrons from their orbits (shells) around nuclei of atoms comprising the sample. This interaction places the atom in an excited (unstable) state. Specimen interaction is what makes Electron Microscopy possible. The inelastic interactions are utilized when examining thick or bulk specimens (SEM). On the bottom side are those examined in thin or foil specimens (TEM).
  • 13. Reactions Exploited In TEM: TEM exploits three different interactions of electron beam-specimen; unscattered electrons (transmitted beam) elastically scattered electrons (diffracted beam) inelastically scattered electrons When incident electrons are transmitted through the thin specimen without any interaction occurring inside the specimen, then the beam of these electrons is called transmitted. The transmission of unscattered electrons is inversely proportional to the specimen thickness. Areas of the specimen that are thicker will have fewer transmitted electrons and so will appear darker, conversely the thinner areas will have more transmitted and thus will appear lighter. Another part of the incident electrons, are scattered (deflected from their original path) by atoms in the specimen in an elastic fashion (no loss of energy). These scattered electrons are then transmitted through the remaining portions of the specimen. All electrons follow Bragg's Law and thus are scattered according to nλ = 2d sinθ where: λ is the wavelength of the rays θ is the angle between the incident rays and the surface of the crystal and d is the spacing between layers of atoms.
  • 14. All incidents that are scattered by the same atomic spacing will be scattered by the same angle. These scattered electrons can be collated using magnetic lenses to form a pattern of spots; each spot corresponding to a specific atomic spacing (a plane). This pattern can then yield information about the orientation, atomic arrangements and phases present in the area being examined. Finally, another way that incident electrons can interact with the specimen is inelastically. These electrons are then transmitted through the rest of the specimen. Inelastically scattered electrons can be utilized in two ways; Electron Energy Loss Spectroscopy (EELS) and Kikuchi Bands.
  • 15. The electromagnetic lenses: When an electric current is passed through the coils (C), an electromagnetic field is created between the pole pieces (P), which forms a gap in the magnetic circuit. By varying the current through the coils, the strength of the field, and thereby the power of the lens, can be varied. This is the essential difference between the magnetic lens and the glass lens. Otherwise they behave similarly and have the same types of aberration: Spherical aberration (Cs – the power in the center of the lens differs from that at the edges), Chromatic aberration (Cc – the power of the lens Varies with the energy of the electrons in the beam), and Astigmatism (a circle in the specimen becomes an ellipse in the image). In a conventional TEM, spherical aberration, which is largely determined by the lens design and manufacture, is the primary limitation to improved image resolution. Chromatic aberration can be reduced by keeping the accelerating voltage as stable as possible and using very thin specimens. Astigmatism can be corrected by using variable electromagnetic compensation coils.
  • 16. The condenser lens system focuses the electron beam onto the specimen under investigation. The objective lens produces an image of the specimen which is then magnified by the remaining imaging lenses and projected onto the viewing device. The objective lens is followed by several projection lenses used to focus, magnify, and project the image or diffraction pattern onto the viewing device. On the way from the source to the viewing device, the electron beam passes through a series of apertures with different diameters. These apertures stop those electrons that are not required for image formation (e.g., scattered electrons). Using a special holder carrying a number of different size apertures, the diameter of the apertures in the condenser lens, the objective lens, and the diffraction lens can be changed as required. Specimen orientation and manipulation: The TEM specimen stage must provide various movements to manipulate and orient the sample. X, Y, and Z translation, and tilt are used to move the appropriate region of the sample into the field of view of the microscope. The basic movements are provided by a goniometer mounted very close to the objective lens.
  • 17. Specimen preparation: A TEM can be used in any branch of science and technology where it is desired to study the internal structure of specimens down to the atomic level. Different thicknesses are required for different applications. For the ultimate high resolution materials studies, the sample cannot be thicker than 20 nm or so; for bio-research, the film can be 300-500 nm thick. In biology, for example, there may be first a chemical treatment to remove water and preserve the tissue as much as possible in its original state, followed by embedding in a hardening resin; after the resin has hardened, slices (sections) with an average thickness of 0.5 μm are cut with an instrument called an ultramicrotome equipped with a glass or diamond knife. The tiny sections thus obtained are placed on a specimen carrier – usually a 3 mm diameter copper specimen grid that has been coated with a structure less carbon film 0.1 μm thick. Cryo (freezing) techniques avoid the sample damage unavoidably caused by conventional drying, fixing, and sectioning preparations.
  • 18. Observing and recording the image: Originally, TEMs used a fluorescent screen, which emitted light when impacted by the transmitted electrons, for real-time imaging and adjustments; and a film camera to record permanent, high resolution images. The screen was under vacuum in the projection chamber, but could be observed through a window, using a binocular magnifier if needed. The fluorescent screen usually hinged up to allow the image to be projected on the film below. Modern instruments rely primarily on solid-state imaging devices, such as a CCD (charge- coupled device) camera, for image capture. They may still include a fluorescent screen, but it may be observed by a video camera. In this text, unless we are discussing specific aspects of the imaging system, we will simply refer to an imaging device. The recent introduction of a direct electron detector promises significant improvements in image resolution and contrast, particularly in signal-limited applications. A conventional CCD camera uses a scintillator material over the image detector elements to convert incident electrons to light, which then creates charge in the underlying CCD element. The scintillator introduces some loss of resolution and the conversion process decreases the efficiency with which electrons contribute to image contrast. Eliminating the scintillator with a direct electron detector improves image resolution and increases detector efficiency by up to three times.
  • 19. A scanning electron microscope, like a TEM, consists of an electron optical column, a vacuum system, electronics, and software. The column is considerably shorter because the only lenses needed are those above the specimen used to focus the electrons into a fine spot on the specimen surface. There are no lenses below the specimen. The specimen chamber, on the other hand, is larger because the SEM technique does not impose any restriction on specimen size other than that set by the size of the specimen chamber. SCANNING ELECTRON MICROSCOPE (SEM) The electron gun at the top of the column produces an electron beam that is focused into a fine spot as small as 1 nm in diameter on the specimen surface. This beam is scanned in a rectangular raster over the specimen and the intensities of various signals created by interactions between the beam electrons and the specimen are measured and stored in computer memory. The secondary electron (SE) signal is the most frequently used signal.
  • 21. • Produce a stream of monochromatic electrons in the electron gun. • Focus the stream using the first condenser lens • The beam is constricted by the condenser aperture (eliminates high-angle electrons). • Second condenser lens is used to form electrons into a thin, tight, coherent beam. • Use objective aperture to limit beam (i.e., eliminate high-angle electrons) • Scan coils raster the beam across the sample, dwelling on the points for a predetermined period of time (selected using scan speed) • Final objective lens focuses beam on desired region. • When beam strikes the sample, interactions occur. We detect what comes out of the sample. SEM: Technical Details:
  • 22. The electron gun and lenses are similar to those described previously for TEM. The most important differences between TEM and SEM are: • Rather than the broad static beam used in TEM, the SEM beam is focused to a fine point and scanned line by line over the sample surface in a rectangular raster pattern. • The accelerating voltages are much lower than in TEM because it is no longer necessary to penetrate the specimen; in a SEM they range from 50 to 30,000 volts. • The specimen need not be thin, greatly simplifying specimen preparation.
  • 23. INTERACTIONS OBSERVED IN SEM: Backscattered electrons (BSE) • Formation – Caused when incident electrons collide with an atom in a specimen that is nearly normal to the path of the incident beam. – Incident electron is scattered backward (“reflected”). • Use – Production varies with atomic number (Z). – Higher Z elements appear brighter than lower Z elements. – Differentiate parts of specimen having different atomic number Secondary Electrons (SE) • Formation – Caused when an incident electron “knocks” and inner shell electron (e.g., k-shell) out of its site. – This causes a slight energy loss and path change in the incident electron and ionization of the electron in the specimen. – The ionized electron leaves the atom with a small kinetic energy (~5 eV). • Use – Production is related to topography. Due to low energy, only SE near the surface can exit the sample. – Any change in topography that is larger than the sampling depth will change the yield of SE. Secondary electrons are more abundant than other types of electrons
  • 24. Auger Electrons (AE): • Formation – De-energization of the atom after a secondary electron is produced. – During SE production, an inner shell electron is emitted from the atom leaving a vacancy. – Higher energy electrons from the same atom can fall into the lower energy hole. This creates an energy surplus in the atom which is corrected by emission of an outer shell (low energy) electron. • Use – AE have characteristic energies that are unique to each element from which they are emitted. – Collect and sort AE according to energy to determine composition. – AE have very low energy and are emitted from near surface regions. X-rays: • Formation – Same as AE. Difference is that the electron that fills the inner shell emits energy to balance the total energy of the atom. • Use – X-rays will have characteristic energies that are unique to the element(s) from which it originated. – Collect and sort signals according to energy to yield compositional information. – Energy Dispersive X-ray Spectroscopy (EDS)
  • 25. The interactions between the beam electrons and sample atoms are similar to those described for TEM: • The specimen itself emits secondary electrons. • Some of the primary electrons are reflected backscattered electrons (BSE). These backscattered electrons can also cause the emission of secondary electrons as they travel through the sample and exit the sample surface. All these phenomena are interrelated and all of them depend to some extent on the topography, the atomic number and the chemical state of the specimen. The most commonly imaged signals in SEM are SE and BSE. Relaxation of excited atoms Inelastic scattering places the atom in an excited (unstable) state. The atom “wants” to return to a ground or unexcited state. Therefore, at a later time the atoms will relax giving off the excess energy. X-Rays, cathodoluminescence and Auger electrons are three ways of relaxation. The relaxation energy is the fingerprint of each element.
  • 26. Secondary and backscattered electrons are conventionally separated according to their energies. When the energy of the emitted electron is less than 50eV, it is referred as a secondary electron and backscattered electrons are considered to be the electrons that exit the specimen with an energy greater than 50eV. Detectors of each type of electrons are placed in the microscope in proper positions to collect them.
  • 27. Electron detection: Detectors for backscattered electrons and secondary electrons are usually either a scintillation detector or a solid-state detector. In the scintillator case, electrons strike a fluorescent screen, which emits light, that is amplified and converted into an electrical signal by a photomultiplier tube. The solid-state detector works by amplifying the minute signal produced by the incoming electrons in a semiconductor device.
  • 28. Specimen preparation: A SEM can be used whenever information is required about the surface or near-surface region of a specimen. It finds application in almost every branch of science, technology, and industry. The only requirement is that the specimen must be able to withstand the vacuum of the chamber and bombardment by the electron beam. If the specimen contains any volatile components such as water, they must be removed by a drying process (or in some circumstances it can be frozen solid) before they can be used in a high vacuum system. Non-conducting specimens will accumulate charge under electron bombardment and may need to be coated with a conducting layer. Iridium gives a fine grained coating and is easily applied in a sputter coater. It gives a good yield of secondary electrons, and consequently, a good quality image of the surface. Cryo preparations are also used in SEM, particularly in biological applications or organic materials (polymers).