Tem or transmitted electron microscopy
378 views
24 slides
Dec 21, 2020
Slide 1 of 24
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
About This Presentation
transmitted electron microscopy
Slide Content
TEM or Transmitted Electron Microscopy
NAME: VIJAYAUMAR.S
ROLL NO:P20BIT1029
1 M.SC BIOTECHNOLOGY
PERIYAR UNIVERSITY
NAME: VIJAYAUMAR.S
ROLL NO:P20BIT1029
1 M.SC BIOTECHNOLOGY
PERIYAR UNIVERSITY
CONTENTS
INTRODUCTION
PRINCIPLE
INSTRUMENT
WORKING PRINCIPLE
APPLICATION
ADVANTAGE
DISADVANTAGE
INTRODUCTION
PRINCIPLE
INSTRUMENT
WORKING PRINCIPLE
APPLICATION
ADVANTAGE
DISADVANTAGE
INTRODUCTION
•In 1931, while conducting research for his
masters at the technical college of Berlin,
Ernst Ruska and Max Knoll designed
first TEM.
•TEM is a microscopy technique in which a
beam of electrons is transmitted through
an ultra thin specimen, interacting with
the specimen.
•In 1931, while conducting research for his
masters at the technical college of Berlin,
Ernst Ruska and Max Knoll designed
first TEM.
•TEM is a microscopy technique in which a
beam of electrons is transmitted through
an ultra thin specimen, interacting with
the specimen.
Electron microscpy involves the study of
different speciman by using an electron
microscopy
Electron microscopy are scientific
instruments use a bean of of energetic
electron to exaime obeject on a very fine
scale.
different speciman by using an electron
microscopy
Electron microscopy are scientific
instruments use a bean of of energetic
electron to exaime obeject on a very fine
scale.
Through the electron microscope we can
see through that we couldnot see in
normal eye.
It has greater magnification than light
microscope
it has 10000+ magnification which is not
possible in current optical microscope
see through that we couldnot see in
normal eye.
It has greater magnification than light
microscope
it has 10000+ magnification which is not
possible in current optical microscope
HISTORY OF TEM
1897-L.J Thomson -Discover the
electron
1924-L Debroglie-Idendified wave length
of electron
1929-E.RusKa-PH.D Thesis on magnetic
lens
1931-Knoll&rusKa-1st electron microscope
built
1938-von borries& rusKa-electron
microscope speciman resolution =10nm
1897-L.J Thomson -Discover the
electron
1924-L Debroglie-Idendified wave length
of electron
1929-E.RusKa-PH.D Thesis on magnetic
lens
1931-Knoll&rusKa-1st electron microscope
built
1938-von borries& rusKa-electron
microscope speciman resolution =10nm
SCALE
TYPES OF ELECTRON MICROSCOPE
TEM-Transmitted electron microscope;
Form image using electron that are
transmitted through a speciman
SEM-Scanning electron microscope;
Utilize that electron have bounced off the
surface of speciman
TEM-Transmitted electron microscope;
Form image using electron that are
transmitted through a speciman
SEM-Scanning electron microscope;
Utilize that electron have bounced off the
surface of speciman
PRINCIPLE OF TEM:
•TEM operates on the same basic
principles as the light microscopebut
uses electrons instead of light. Since, light
microscope is limited by the wavelength of
light. TEMs use electrons as a “light
source”and their much lower
wavelength makes it possible to get a
resolutiona 1000 times better than with a
light microscope
•TEM operates on the same basic
principles as the light microscopebut
uses electrons instead of light. Since, light
microscope is limited by the wavelength of
light. TEMs use electrons as a “light
source”and their much lower
wavelength makes it possible to get a
resolutiona 1000 times better than with a
light microscope
Resoultion & magnification
MICROSCOPE RESOLUTION MAGNIFICATION
ELECTRON
MICROSCOPY
0.2nm 500000x
OPTICAL
MICROSCOPY
200nm 1000x
MICROSCOPE RESOLUTION MAGNIFICATION
ELECTRON
MICROSCOPY
0.2nm 500000x
OPTICAL
MICROSCOPY
200nm 1000x
TRANSMITTED ELECTRON MICROSCOPY CONTAIN
A simplified ray diagram of TEM consists
Electron source
condenser lens with aperture
speciman
objective lens with aperture
projector lens and
fluorescent screen
A simplified ray diagram of TEM consists
Electron source
condenser lens with aperture
speciman
objective lens with aperture
projector lens and
fluorescent screen
DESIGN OF TEM
ELECTRON GUN
The electron beam is generated in the
electron gun two types of gun are used
Thermionic gun:
Tungsten filament
Lanthanum hexaboride
Field emission gun:
Field emitter or schotty emitter
The electron beam is generated in the
electron gun two types of gun are used
Thermionic gun:
Tungsten filament
Lanthanum hexaboride
Field emission gun:
Field emitter or schotty emitter
ELECTRON SOURCE
•The electron are form when we are heat
the tungsten filament in electron gun
•The lot of electron are produce from
electron gun
•The electron are form when we are heat
the tungsten filament in electron gun
•The lot of electron are produce from
electron gun
CONDENSER &OBJECTIVE LENS
CONDENSER Lens:
•control spot sizes and illumination area on
sample.
•OBJECTIVE Lens:
•Images sample and is strongest lens in
the system.
•Both lenses are made up ofElectro
magnetic lens
CONDENSER Lens:
•control spot sizes and illumination area on
sample.
•OBJECTIVE Lens:
•Images sample and is strongest lens in
the system.
•Both lenses are made up ofElectro
magnetic lens
PROJECTOR &DECECTORS
projector lenses:
changes modes from diffraction to imaging.
Detectors:
various different configurations designed
to collect secondary signals produced by
the high-energy electron beam.
projector lenses:
changes modes from diffraction to imaging.
Detectors:
various different configurations designed
to collect secondary signals produced by
the high-energy electron beam.
WORKING PRINCIPLE
•A heated tungsten filamentin the
electron gunproduces electronsthat get
focus on the specimen by the condenser
lenses.
•Magnetic lenses are used to focus the
beam of electrons of the specimen.
•column tube of the condenser lens into the
vacuum creating a clear image, the
vacuum allows electrons to produce a
clear image without collision with any
airmolecules which may deflect them.
•A heated tungsten filamentin the
electron gunproduces electronsthat get
focus on the specimen by the condenser
lenses.
•Magnetic lenses are used to focus the
beam of electrons of the specimen.
•column tube of the condenser lens into the
vacuum creating a clear image, the
vacuum allows electrons to produce a
clear image without collision with any
airmolecules which may deflect them.
•On reaching the specimen, the specimen scatters the
electrons focusingthem on the magnetic lenses
forming a large clear image, and if it passes through a
fluorescent screen it forms a polychromatic image.
•The denser the specimen, the more the electrons are
scattered forming a darker image because fewer
electron reaches the screen for visualization while
thinner, more transparent specimens appear brighter.
electrons focusingthem on the magnetic lenses
forming a large clear image, and if it passes through a
fluorescent screen it forms a polychromatic image.
•The denser the specimen, the more the electrons are
scattered forming a darker image because fewer
electron reaches the screen for visualization while
thinner, more transparent specimens appear brighter.
RESULTS
Applications of TEM
1.TEM is used in a wide variety of fields
From Biology, Microbiology,
Nanotechnology, forensic studies
2.To visualize and study cell structures of
bacteria, viruses, and fungi
3.To view bacteria flagella and plasmids
4.To view the shapes and sizes of microbial
cell organelles
5.To study and differentiate betweenplant
and animal cells.
1.TEM is used in a wide variety of fields
From Biology, Microbiology,
Nanotechnology, forensic studies
2.To visualize and study cell structures of
bacteria, viruses, and fungi
3.To view bacteria flagella and plasmids
4.To view the shapes and sizes of microbial
cell organelles
5.To study and differentiate betweenplant
and animal cells.
Application
6.Its also used in nanotechnology to study
nanoparticles such as ZnO nanoparticles
7.It is used to detect and identify fractures,
damaged microparticles which further
enable repair mechanisms of the particles.
6.Its also used in nanotechnology to study
nanoparticles such as ZnO nanoparticles
7.It is used to detect and identify fractures,
damaged microparticles which further
enable repair mechanisms of the particles.
Advantage of TEM
1.It has a very powerful magnification of about 2
million times that of the Light microscope.
2.It can be used for a variety of applications
ranging from basic Biology to Nanotechnology,
to education and industrial uses.
3.It can be used to acquire vast information on
compounds and their structures.
4.It produces very efficient, high-quality images
with high clarity.
5.It can produce permanent images.
6.It is easy to train and use the Transmission
Electron Microscope
1.It has a very powerful magnification of about 2
million times that of the Light microscope.
2.It can be used for a variety of applications
ranging from basic Biology to Nanotechnology,
to education and industrial uses.
3.It can be used to acquire vast information on
compounds and their structures.
4.It produces very efficient, high-quality images
with high clarity.
5.It can produce permanent images.
6.It is easy to train and use the Transmission
Electron Microscope
LIMITATIONS
1.Generally, the TEMs are very expensive to purchase
2.They are verybig to handle.
3.The preparation of specimens to be viewed under the
TEM is very tedious.
4.The use of chemical fixations, dehydrators, and
embedments can cause the dangers of artifacts.
5.They are laborious to maintain.
6.It requires a constantinflow of voltage to operate.
7.They are extremely sensitive to vibrations and electro-
magnetic movements hence they are used in isolated
areas, where they are not exposed.
8.It produces monochromatic images,unless they use a
fluorescent screenat the end of visualization.
1.Generally, the TEMs are very expensive to purchase
2.They are verybig to handle.
3.The preparation of specimens to be viewed under the
TEM is very tedious.
4.The use of chemical fixations, dehydrators, and
embedments can cause the dangers of artifacts.
5.They are laborious to maintain.
6.It requires a constantinflow of voltage to operate.
7.They are extremely sensitive to vibrations and electro-
magnetic movements hence they are used in isolated
areas, where they are not exposed.
8.It produces monochromatic images,unless they use a
fluorescent screenat the end of visualization.
THANK YOU
Categories
GeneralDownload
Download Slideshow Get the original presentation fileQuick Actions
Statistics
- Views 378
- Slides 24
- Favorites 2
- Age 1807 days
Related Slideshows
22
Pray For The Peace Of Jerusalem and You Will Prosper
RodolfoMoralesMarcuc
30 views
26
Don_t_Waste_Your_Life_God.....powerpoint
chalobrido8
32 views
31
VILLASUR_FACTORS_TO_CONSIDER_IN_PLATING_SALAD_10-13.pdf
JaiJai148317
30 views
14
Fertility awareness methods for women in the society
Isaiah47
29 views
35
Chapter 5 Arithmetic Functions Computer Organisation and Architecture
RitikSharma297999
26 views
5
syakira bhasa inggris (1) (1).pptx.......
ourcommunity56
28 views