Beam of electrons is transmitted through an ultra thin specimen,
An image is formed from the interaction of the electrons transmitted through the specimen,
The image is magnified and focused onto an imaging device, such as a fluorescent screen, on a layer of photographic film, or to be detected by a sensor such as a CCD camera
4. OPTICAL MICROSCOPE
1. Uses optical glass lens
2. Have low
magnification (500X or
1000X appx.)
3. Does not require
vaccum for operation.
4. Small depth of field.
5. Low price.
6. Beam of electrons is transmitted through an ultra thin
specimen,
An image is formed from the interaction of the
electrons transmitted through the specimen,
The image is magnified and focused onto an imaging
device, such as a fluorescent screen, on a layer of
photographic film, or to be detected by a sensor such as
a CCD camera
TRANSMISSION ELECTRON MICROSCOPE
8. TEM gives Information about ,
Topography :
The surface features of an object
Morphology:
The shape and size of the particles
Composition:
The elements and compounds that the object is
composed
Crystallographic Information:
How the atoms are arranged in the object
10. The Lenses in TEM
Condenser lenses(two)-control how
strongly beam is focused (condensed)
onto specimen. At low Mag. spread
beam to illuminate a large area, at high
Mag. strongly condense beam.
Objective lens-focus image (image
formation) and contribute most to
the magnification and resolution of the image.
Four lenses form magnification
system-determine the magnification
of the microscope. Whenever the
magnification is changed, the currents
through these lenses change.
B
11. Sample Preparation
• Dehydration in alcohol
• Embedding in resin
• Semi-thin sections cut at 0.5 micron thick,
stained with toluidine blue
• Selection of sample blocks
• Ultrathin sections at 0.1 micron thick, stained
with lead citrate and uranium acetate
12. Principle of TEM
• Illumination - Source is a beam of high
velocity electrons accelerated under vacuum,
focused by condenser lens (electromagnetic
bending of electron beam) onto specimen.
• Image formation - Loss and scattering of
electrons by individual parts of the specimen.
Emergent electron beam is focused by
objective lens. Final image forms on a
fluorescent screen for viewing
14. Imaging in TEM
• Two principal kinds
• Diffraction contrast imaging; BF and DF
• Use either an non-diffracted or diffracted beam
and remove all other beams from the image by the
use of an objective aperture.
• Phase contrast or high resolution imaging HREM
use all of the diffracted and non-diffracted beams
and add them back together. Phase and intensity
to form a phase contrast image.
15.
16. TEM Operation
• Tedious operation
• Time consuming
• Works in the dark
• Photography required
17. Working of TEM
• High electron beam bombardment.
• Lenses focus it onto the specimen
• Electrons are used for image construction
• Image is constructed by the transmitted
electrons
• Thicker region occlude more beam
18. Working of TEM
• In areas in the object where these electrons
encounter atoms with a heavy atomic nucleus,
they rebound.
• In regions where the material consists of
lighter atoms , the electron are able to pass
through.
19. TEM Uses in Biomedical
• Renal diseases
• Typing of tumors
• Muscle diseases
• Skin diseases
• Miscellaneous diseases
20. Advantages
• High resolution and magnification
• Give information of Element and Compound
• Detailed image obtain