Transcript lecture2

The Transmission
Electron Microscope
Bob Ashley 6-21-2013
Overview
• Systems of the TEM
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Illumination
Condenser lens system
Specimen manipulation stage
Imaging system
Image formation
Magnification
Recording system
Reading List
Practical Electron
Microscopy for
Biologists. G. A. Meek.
The Transmission Electron
Microscope
Bizzola Electron Microscopy 1999
JEOL 2100 Lab6
Illumination System
Thermionic Emission Source
• Electron source or gun
• Provides first coherent crossover of electron beam
• High voltage leading to filament- heated metal wire (cathode)
• Tungsten or Lab6 (lanthanum hexaboride)
• Work function
• Energy necessary to bring about
electron emission
• Electrons would have no order
• Wehnelt Cap
• Electrode that shapes and controls emission
• Negative relative to filament
• Anode
• Positive respective to filament
Wikipedia
Source Types
• Tungsten
• Wire filament
• Lab6
• Lanthanum hexaboride
crystal
• Field Emission Gun
• Tungsten tip
• Thermionic (Schotkky) and Cold
Field Emission
Source
Allows for emission of electrons
from fine tip via charge
differential of tip and anodes.
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Brighter
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More coherent source
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Atomic diameter point
source is future of FE guns
Coherent or Incoherent
• Coherent
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Waves have same wavelength and phase, in the ideal sense would
be perfectly coherent
• Incoherent
• Waves have modulating phase relationships and wavelengths
• Temporal coherency
• Wavelength differential
• Spatial coherency
• Size of source
Temporal coherence length=
product of velocity and planks
constant divided by the energy
spread
Spatial coherence length=
wavelength divide by 2 times
the alpha (angle formed from
source at at the specimen)
Comparing the Electron
Sources
Condenser Lens
and Aperture
Condenser Lenses
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C1 is spot size
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C2 is beam brightness knob
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Varies and magnifies C1
Aperture is a physical aperture
in range of sizes
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Determines size of beam on
specimen
Reduces spherical aberration
Associated stigmator to correct
astigmatism
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www.matter.org.uk/
Left Control Box
Specimen Chamber
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Vacuum interlock system
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Specimen Holder and Stage
• Holds sample in place on top of copper grid
• Moved with stage in x,y,z
• Tilting holder
• Side or top entry
• Room temperature
• Cryo holder
Stage Controller
Grid Types
• Supports used must be strong yet electron transparent
• Plastic (formvar)
• Carbon
• Holey carbon
• Quantifoil
• C-flat
Image Formation
• Four fundamental processes
• Scattering
• Absorption
• Gives rise to amplitude contrast
• Contrast from absence of electrons
• Diffraction
• Used to enhance contrast in cryoEM but with loss of resolution
• Interference
• Gives rise to phase contrast
• Halo or fringe around object
Specimen Beam Interactions:
Scattering
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Elastic (Rutherford scattering)
• Electron collides with or passes close to a nucleus of atom, no loss of energy of initiating
electron
• changes direction without losing velocity or
energy
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Inelastic
• Electron collides with cloud electrons,
measurable loss of energy of initiating electron
• As sample thickness increases more electrons
are backscattered
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Assumed to occur only once in TEM (either the e- scatters or it doesn’t)
• Sometimes referred to as the direct transmitted beam if no scattering occurred
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Can either forward or back scatter
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Scatter measured in spatial deviation manifests as contrast, scatter of angular deviation
manifests as diffraction patterns
Scattering and Coherence
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Coherence
• Electrons remain in phase
with one another after
passing through sample
• Incoherent electrons are those
that have no consistent phase
relationship upon passing
through sample
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Elastic
• Usually coherent
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Inelastic
• Almost always incoherent
Accelerating Voltages
• How does this all relate in choice of your electron
accelerating voltage or kV?
• The faster the speed of the electrons the better
resolution obtained
• But at the sacrifice of contrast
• Slower electron speeds have more opportunity for
inelastic scattering, inelastic scattering produces energy
(heat) therefore lower kV has more specimen damage
Mass Thickness
Typical thick sections are at
100nm while high resolution is
limited to 10’s of nm.
Objective Lens
and Aperture
Objective Lens
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Most important lens
• Forms initial image further magnified by other
lenses
• Responsible for focus
• Blocking of more peripherally deflected electrons
with Objective aperture
• The larger the aperture used the more phase
contrast
• Important for cryo EM and higher resolution
• The smaller the aperture the more aperture
contrast
• Associated stigmator to correct any astigmation
Objective Aperture
Bozzola 176
Right Controller Box
Intermediate and Projections
Lenses
Similar in construction to
objective lens
Major function is to assist in
the magnification of the image
from the objective lens
The Screen and CCD
Next Week:
CCDs and their function in the
electron microscope