Electron Microscopy (TEM and SEM)
Summary
TLDRThe video discusses the evolution from light microscopy to electron microscopy, highlighting how electron microscopes provide over 1,000 times better resolution by using electron beams instead of light. Transmission Electron Microscopy (TEM) allows scientists to visualize small structures like proteins by recording electron energy after passing through specimens, while Scanning Electron Microscopy (SEM) captures secondary electrons emitted from specimen surfaces to study topography. Both methods offer high magnification but have limitations, such as their inability to study live specimens. They are also expensive and require extensive training.
Takeaways
- π¬ Light microscopy was the standard until the mid-20th century, but it still plays an important role today.
- ποΈ Light microscopes can visualize individual cells but struggle to show structures smaller than a cell.
- π§ͺ Electron microscopy, developed in the 1930s and 40s, allowed scientists to see smaller structures with higher resolution.
- π Electron microscopes can magnify specimens up to 1,000,000 times and achieve a resolution of 0.2 nanometers.
- β‘ Electron microscopy uses beams of electrons, which interact with specimens for more detailed imaging than light microscopes.
- 𧫠Transmission Electron Microscopy (TEM) uses electron beams passing through ultra-thin, stained specimens to visualize internal structures.
- π οΈ TEM requires specimens to be dehydrated, embedded in resin, and sliced thinly, making it unsuitable for studying live specimens.
- ποΈ Scanning Electron Microscopy (SEM) creates 3D images by detecting secondary electrons emitted from the specimenβs surface.
- π‘ SEM visualizes the topography of specimens, providing detailed surface structure analysis, unlike TEMβs flat images.
- π° Both SEM and TEM are expensive and complex techniques that require extensive training, limiting their use outside specialized fields.
Q & A
What limitations did standard light microscopy have in studying microscopic structures?
-Light microscopy could visualize individual cells, but it struggled to resolve structures smaller than cells, such as proteins and viruses, which limited its ability to study these smaller details.
How does electron microscopy achieve higher resolution than light microscopy?
-Electron microscopy uses beams of electrons with much shorter wavelengths than visible light. This allows for much higher resolution and magnification, up to 1,000,000 times, compared to light microscopy.
What is Transmission Electron Microscopy (TEM), and how does it work?
-TEM uses a beam of electrons transmitted through a specimen to produce highly detailed images. The specimen is stained with heavy metals, and electrons lose energy when passing through electron-dense regions, allowing the microscope to visualize structures like cell organelles and proteins.
What preparation is required for a specimen to be viewed using TEM?
-The specimen must be dehydrated, embedded in plastic resin, and sliced into ultra-thin sections with a glass or diamond knife. These sections allow the electron beam to pass through for imaging.
What is Scanning Electron Microscopy (SEM), and what does it specialize in visualizing?
-SEM specializes in studying the surface topography of samples by scanning the surface with an electron beam. The specimen is coated with vaporized gold or palladium, and the emitted secondary electrons help create a 3D image of the surface.
What are the main differences between TEM and SEM?
-TEM visualizes internal structures with high resolution but produces flat images, while SEM focuses on surface topography and provides 3D images. TEM has better resolution, but SEM can visualize surface details in three dimensions.
What are some limitations of electron microscopy techniques like TEM and SEM?
-Both techniques cannot be used to study living specimens, as the samples must be dehydrated and processed. Additionally, they are expensive and require extensive training to operate.
What role do heavy metal stains play in TEM imaging?
-Heavy metal stains like uranyl acetate or osmium tetroxide bind to certain parts of the specimen, making them electron-dense. These regions absorb more electrons, which results in a higher contrast in the final image.
How are secondary electrons used in SEM imaging?
-When the electron beam interacts with the surface of a specimen coated with gold or palladium, it causes the emission of secondary electrons. These electrons are then detected and used to visualize the surface features of the specimen.
Why is electron microscopy important in microbiology?
-Electron microscopy allows microbiologists to study incredibly small structures, such as viruses, proteins, and cellular organelles, which are not visible with standard light microscopy. This has led to significant advancements in understanding the microscopic world.
Outlines
π¬ The Evolution from Light Microscopy to Electron Microscopy
This paragraph discusses the transition from light microscopy, which was dominant until the mid-20th century, to electron microscopy. As scientists became curious about structures smaller than cells, they needed more advanced tools. Electron microscopy, developed in the 1930s and 40s, offered a higher resolution, with some techniques achieving up to 0.2 nanometers, over 1,000 times better than light microscopes. This advancement allowed researchers to study finer details such as proteins and viral structures, enhancing their understanding of the microscopic world.
βοΈ How Electron Microscopy Works: Electrons Over Light
This section explains the working principle of electron microscopy, which uses beams of electrons instead of light. Electrons have a shorter wavelength than visible light, allowing for greater detail and resolution. The paragraph introduces Transmission Electron Microscopy (TEM), which involves embedding specimens in resin or staining them with heavy metals. These stained areas, called electron dense regions, lose more energy when electrons pass through, enabling high-resolution imaging. The specimen is sliced thin to allow electrons to pass through, and the image is magnified and projected using fluorescent screens and a camera.
π§ Preparing Specimens for Transmission Electron Microscopy (TEM)
This section describes the process of preparing specimens for TEM. Specimens are dehydrated, embedded in plastic resin, and sliced into ultra-thin sections using a glass or diamond knife. These thin sections allow electrons to pass through and visualize the specimen. The electron beam is generated and accelerated through the microscope column, passing through the specimen. After passing through the electron-dense regions, the beam is magnified and projected onto a fluorescent screen, which converts electron energy into visible light for imaging.
π§ͺ How Transmission Electron Microscopy (TEM) Visualizes Samples
Here, the paragraph goes into more detail about the electron beam's journey. After passing through the specimen, the electrons lose energy based on the electron-dense regions, then go through objective and projector lenses that further magnify the image. Finally, the fluorescent screen translates the electron interactions into bright spots, with a camera capturing the final image. This allows TEM to visualize ultra-small structures like cell organelles, proteins, and cytoskeletal filaments. However, it is noted that TEM's limitations include its inability to image living specimens or 3D structures.
π» Introduction to Scanning Electron Microscopy (SEM)
This paragraph introduces Scanning Electron Microscopy (SEM), which differs from TEM by visualizing surface structures. SEM specimens are coated with vaporized gold or palladium ions, and the emitted secondary electrons from the surface are detected to produce an image. Unlike TEM, SEM can visualize 3D structures but has lower resolution. Both methods require extensive training and are costly, making them tools mostly for specialized microbiology research.
π How SEM Works: Scanning and Electron Detection
SEM operates by accelerating an electron beam towards the specimen, which is scanned across its surface. As electrons hit the gold- or palladium-coated surface, secondary electrons are emitted and detected. There are two detectors: the secondary electron detector and the backscatter electron detector, the latter used for crystallography and magnetic studies. However, microbiologists focus on secondary electrons to visualize surface topography, as SEM produces a 3D image by scanning the surface of the sample.
πΈ The Strengths and Weaknesses of SEM
The advantages of SEM are outlined here, particularly its ability to provide 3D images and study surface topography, unlike TEM, which produces 2D images. SEM is useful for exploring depth and surface structures, but it also has limitations, including lower resolution compared to TEM and the inability to image living specimens. Both SEM and TEM require expensive equipment and advanced training, restricting their use to specialized fields.
π Summary of Electron Microscopy: A Powerful but Limited Tool
This final paragraph summarizes the key points covered in the tutorial. Electron microscopy, offering 1,000 times better resolution than light microscopy, uses electron beams for imaging due to their shorter wavelength. TEM is used to study internal cellular structures through electron-dense regions, while SEM is used for 3D surface imaging. Both methods are essential in microbiology but are limited by their inability to study living organisms and their high cost and complexity.
Mindmap
Keywords
π‘Light Microscopy
π‘Electron Microscopy
π‘Resolution
π‘Transmission Electron Microscopy (TEM)
π‘Scanning Electron Microscopy (SEM)
π‘Electron Dense Regions
π‘De Broglie Wavelength
π‘Secondary Electrons
π‘Fluorescent Screen
π‘Magnification
Highlights
Light microscopy was the standard until the mid-20th century and remains useful today.
Electron microscopy, developed in the 1930s and 40s, offers much higher resolution than light microscopy.
Electron microscopes can achieve a resolution of 0.2 nanometers, 1,000 times better than light microscopy.
Electron microscopes can magnify specimens up to 1,000,000 times their original size.
Electron microscopy allows the study of smaller structures like proteins and viruses, which cannot be visualized by light microscopy.
Electron microscopes use beams of electrons with a shorter wavelength than visible light, providing higher resolution.
Transmission Electron Microscopy (TEM) visualizes fine cellular structures using heavy metal stains.
TEM requires specimens to be dehydrated, embedded in resin, and cut into ultra-thin slices.
TEM detects electron-dense regions where electrons lose energy as they pass through, creating detailed images.
Scanning Electron Microscopy (SEM) visualizes surface topography by detecting secondary electrons emitted from the specimen.
In SEM, the specimen is coated with vaporized gold or palladium to enhance electron interactions.
SEM produces 3D images of the specimen surface, unlike the flat images from TEM.
TEM is used to study internal cell structures like organelles, while SEM is better for surface topography.
Both SEM and TEM cannot visualize living specimens, as they require dehydration and coating.
Electron microscopy techniques are expensive, complicated, and primarily used by researchers in fields like microbiology.
Transcripts
We just learned all about light microscopy, which was the standard until the middle of
the 20th century, and remains tremendously useful today.
But as we began to learn more about the microscopic world, using light microscopes that could
visualize individual cells, we started to become curious about structures that are smaller
than a cell, some details of which were difficult to visualize and study under standard light
microscopes.
Fortunately, electron microscopy, developed in the 1930s and 40s, proved to be much more
powerful and allowed scientists to view these smaller structures.
Some electron microscopy techniques employ a resolution of 0.2 nanometers, which is more
than 1,000 times better than light microscopy.
With this higher resolution, electron microscopes are able to magnify their specimen up to 1,000,000
times their original size, allowing researchers to study proteins inside of cells, and the
molecular structure of viruses, all of which led to a better understanding of the microscopic
world.
Of course we have to ask, how do they do this?
Well the answer is in the name, they use beams of electrons, which interact with the sample
as the beam is transmitted through the specimen.
As we recall from our study of chemistry, electrons are stable, subatomic particles
that carry a negative charge.
Electron beams have a much shorter wavelength than the visible light that light microscopes
use, which we refer to as the de Broglie wavelength, as we learned in the modern physics series.
This shorter wavelength allows for a higher level of detail and resolution in imaging.
One type of electron microscroscopy is called Transmission Electron Microscopy, or TEM.
For TEM, specimens are fixed on a support grid and either embedded in resin or stained
with a material like uranyl aceate or compounds of heavy metals like osmium tetroxide.
Certain structures within the specimen will take up more of the stain than other parts
of the specimen, and those sections are called electron dense regions.
When electrons pass through electron dense regions they lose more energy compared to
when they pass through sparser regions.
This phenomenon is used by TEM to visualize the specimen at high levels of resolution
and magnification.
For the stained specimen to be viewed by TEM it must be dehydrated, embedded in plastic
resin, and cut into ultra-thin slices with a glass or diamond knife.
The sections must be ultra-thin so that the electrons can pass through them.
When the specimen is secured in the specimen holder, an electron beam is generated and
shot out of the electron gun.
The electron beam is accelerated down the column of the microscope after passing through
the anode.
The electron beam then passes through the specimen, once again, losing energy as electrons
pass through electron dense regions.
The electrons then pass through the objective lens, magnifying the image, before the electrons
pass through the projector, or ocular lens, which magnifies the image further and projects
it onto the fluorescent screen.
This is where we start translating the electrons into an image.
The fluorescent screen is coated with a chemical which appears as bright spots when electrons
come into contact with it.
The intensity of the bright spot depends on how much energy the electrons have when they
hit the fluorescent screen.
The camera under the fluorescent screen then captures the image made from the bright spots
which is displayed on a computer screen.
Transmission electron microscopes are used to visualize structures that are too small
to study with light microscopes such as the cell organelles, proteins, cytoskeletal filaments,
and the components of cell membranes.
But even with the unmatched resolution and magnification abilities of TEM, it still does
have its limitations.
Some of these include the fact that you cannot study living specimens or image 3D structures
because the specimens must be dehydrated and cut into ultra-thin slices before imaging.
The second type of electron microscopy is Scanning Electron Microscopy, or SEM.
With SEM, specimens are coated with vaporized gold or palladium ions, because when electrons
come into contact with this coating, they cause atoms on the surface of the specimen
to emit electrons.
These emitted electrons are called secondary electrons, and these are what SEMs use to
visualize their specimen.
After the coated specimen is secured on the stage of the SEM, the process starts out similarly
to TEM in that an electron beam is shot out and accelerated towards the specimen.
In the SEM, the electron beam then sweeps, or scans the surface of the specimen, which
causes it to discharge secondary electrons.
There are two types of detectors in the sample chamber, the secondary electron detector and
the backscatter electron detector.
The backscatter electron detector picks up backscatter electrons that come from deeper
regions of the sample that are a result of elastic interactions between the beam and
the sample.
The results from this detector are primarily used to look at crystallography, and the magnetic
field of the sample.
But for the purposes of microbiology, researchers focus on the detection of secondary electrons
which allow them to visualize the topography of the sample, or the distribution of parts
and features on the surface of the sample.
The detectors convert the electron signal into a light signal that is amplified by passing
through a photomultiplier before the final image is projected on a computer screen.
SEM imaging is primarily used to study the topography of cells and other similar structures.
With this type of microscopy, researchers are able to investigate the depth of structures,
which isnβt possible with TEM, as SEM produces a 3D image opposed to the flat image from
TEM.
Yet, just like TEM, SEM cannot visualize live specimens, and SEM has worse resolution than
TEM.
Both TEM and SEM are expensive and require a lot of training, so they are not likely
to be used apart from those pursuing a microbiology career.
We covered quite a lot in this tutorial, so letβs briefly summarize.
Electron microscopy has around 1,000 times better resolution than light microscopy because
electron microscopy uses electron beams instead of light, which have a shorter wavelength.
This allows some electron microscopes to visualize specimens at 1,000,000 times their original
size.
Transmission Electron Microscopy, or TEM, records the differing energies that electrons
possess after they pass through a specimen stained with heavy metals to visualize small,
detailed structures like proteins inside of cells, and molecules associated with viral
particles.
Scanning Electron Microscopy, or SEM, captures the secondary electrons that are emitted from
the surface of samples coated in vaporized gold or palladium ions to visualize the topography
of the specimen.
And the main drawback, as we mentioned, is that both SEM and TEM cannot be used to visualize
living specimens, and they are also quite expensive and complicated techniques to use.
And with that, we know a bit about electron microscopy.
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