Describe the changes in the field of view and the amount of available light when going from low

Let’s suppose that there is a microscope that has a 20X ocular (eyepiece) and twoobjectives of 10X and 43X respectively. Then the low-power magnification of thismicroscope would be:(Eyepiece magnification) x (Objective magnification) = (Total Magnification)(20) x (10) = (200X)Also, the high-power magnification of this microscope would be:(Eyepiece magnification) x (Objective magnification) = (Total Magnification)(20) x (43) = (860X)There are three steps to make a proper wet mount of the letter “e”. First, place the letter“e” from the newspaper on the clean glass slide. Then, put a drop of water on the specimenusing a pipette. Finally, place a clean coverslip and remove any excess water at the edge.Make sure when putting a coverslip, the lower one edge of the coverslip so that it touches theside of the drop of water at about a 45 degrees angle. Also, lower the coverslip slowly using aneedle or probe.When going from low to high power using the compound microscope, the field of viewand the amount of available light changes. The field of view narrows down and gets smalleras the objectives uses higher power. Also, the amount of available light decreases when goingfrom low to high-power objectives.Therefore, the user may have to combat the problems incurred with the microscope whenthe power changes from low to high. Since the field of view gets smaller, the user may movethe stage around and observe the specimen. He may also adjust diaphragm so that there isappropriate amount of light that would not hurt his eye.In addition, the procedure for using the microscope differs slightly under high-power asopposed to low-power. When using a low-power objective, a coarse adjustment knob shouldbe used to focus the image, unless it is very easy to damage both the slide and the objective.On the other hand, when using a high-power objective, use a fine adjustment knob to focusthe image sharply, since the specimen is generally focused when using a low-power objectivepreviously.Other than the compound light microscope, there is also a microscope calledstereomicroscope. Unlike the compound light microscope which gives two-dimensionalviews, the stereomicroscope gives three-dimensional image. Therefore, stereomicroscopesare often called dissecting microscopes because they offer the depth of field which isnecessary to control the objects while observing them.In addition to light microscopes, there is another type of microscopes - electronmicroscopes. Electron microscopes use beams of electrons, not light, to produce images.Electron microscopes can present more clear images of even smaller objects compared to thelight microscopes. Electron microscopes are classified into two main types: transmissionelectron microscopes (TEMs) and scanning electron microscopes (SEMs). TEMs shine abeam of electrons through a thin specimen, and thus they reveal very details inside the cell.

SEEING IS BELIEVING

Microscopes that use visible light to view the microscopic world are broadly categorized as "light microscopes".

Compound Microscopes are a type of light microscope that uses a series of 2 lenses in order to achieve higher magnifying power than simple microscopes having only one lens (also known as "dissecting microscopes".) When using a compound microscope, specimen must be placed on a transparent microscope slide and covered with a transparent cover slip in order to view. The specimen is then placed on the stage of the microscope over the light source to allow light to pass through the specimen. The illuminated specimen is viewed through 2 magnifying lenses; 1) the magnifying lens of the objective located on the rotating nose-piece which is positioned directly over the specimen, and 2) the magnifying lens located in the eye-pieces. The eyepieces have a fixed magnification of 10X. The rotating nosepiece will have an array of objectives ranging from 4X up to perhaps 100X, depending on the microscope. Each objective is clearly marked indicating its magnification power.

The field of view DECREASES as you INCREASE magnification.
The amount of light observed through the microscope gets dimmer (is reduced) as you increase magnification.

You should notice that your DEPTH OF FOCUS decreases as magnification INCREASES. This means that with a relatively small movement of the fine focus knob, you could be out of the focal range. For looking at cells, you will notice you will see fewer layers of cells at higher magnifications.

You can measure the actual length of your field of view by viewing a ruler or standardized grid with millimeter demarcations using the 10 X objective. count the number of mm in your field of view, then convert to micrometers. (1000um = 1mm).

You should notice that the image you see is UP-SIDE-DOWN and REVERSED. This phenomenon is called INVERSION.
Due to INVERSION, when you move the slide to the RIGHT, the image of the slide that is seen through the oculars (or eye-pieces) appears to move LEFT. And, when you move the slide to the LEFT, the image of the slide that is seen through the oculars (or eye-pieces) appears to move RIGHT.
This means the object will appear to move in the OPPOSITE direct as it is being moved in reality.

Inversion is term used for the reversal of an image projected by a compound microscope. Compound microscopes have more that one magnifying lens. In most educational institutions, students use compound microscopes that contain 2 magnifying lenses. One of the magnifying lenses is called the OBJECTIVE. Typically, an array of objectives are screwed into the rotating nose-piece of the microscope, each having different magnifying power. The lowest power objective is the 4X objective, also called the "scanning" objective. This term is used, because the 4X objective should be used first, when viewing a new slide. The 4X objective have a wide field of view and a long focal length, which makes finding the specimen (or the area of interest) on the slide easier to find. There should also be a low powered objective that is a 10X objective and a high-powered objective that is 40X. Some microscopes may also have a 20X and / or 100X, etc. The second magnifying lense is not interchangeable and lies in the oculars themselves. The oculars will almost always have a magnifying power of 10X.
A light source underneath the sample projects light upward through the sample and into an object lens. The objective lens is curved, thus causing the light that passes through it to cross over, thus inverting the image. The light then passes through the ocular lens, or the lens that you actually loo through with your eyes. Because the ocular lens is usually a simple lens, the inversion remains and you see the image inverted.

Introduction to the Compound Microscope

The compound microscope allows us to magnify objects up to 1000 times (with a 100X objective). We can calculate the magnification we are observing with the microscope by multiplying the magnification power of the objective, by the magnification power of the eyepieces. The magnification of the eyepieces is always 10X. There fore, If you are using the 40X objective, the object you are viewing under the microscope would be magnified 400 times more than with the naked eye. If we do the math, we see that 10X times 40X equals 400X. Compound microscopes are good for viewing up to 1 micrometer, or 100 nanometers (nm).

Physicist Ernst Ruska and electrical engineer Max Knoll constructed the first electron microscope in 1931.

(Side note about EM) In order to view even smaller objects, we would have to go to using a method that does not depend upon light. This is because the wavelength of visible light itself is only between 390 nm and 700 nm. At these small levels we can use electron microscopes since they utilize the wavelengths of electrons to visualize the specimen which are several orders of magnitude smaller than the wavelength of visible light. With electron microscopes we can visualize objects as small as 0.5 nm.

I. HANDLING

Before using the compound microscope, it is important to know how to handle and care for it. When transporting the microscope, it is very important to make sure that you have a good grip on the scope and carry it with 2 hands at all times. One hand should be placed on the base of the scope while the other should be placed on the body (see diagram). The scopes are not necessarily heavy, but their center of mass is at the base, making it unstable if supporting by one hand alone. You must also be sure that any cords are wrapped up and secured before supporting so as to not trip over the cord or create a hazard for others around you to possibly trip and fall.

Skipping or overlooking any steps could result in very costly damage to the objectives, eyepieces or other microscopic parts. Please take care to read instruction first, before doing each and every step.

1) Place microscope gently on the counter at your workstation.
2) Ensure that the scope is away from any edges so that it will not fall or get knocked over.
3) Plug in the microscope.
4) Locate the ON/OFF switch and turn the microscope ON.
5) Locate the LIGHT LEVEL adjustment and turn the light down so you do not hurt your eyes with bright light.
6) Use the COARSE FOCUS knob to move the stage all the way toward the bottom (base) of the scope (if it is not already there).
7) Once the stage is all the way down, you can safely rotate the NOSEPIECE to select different powered objectives.
8) Locate the 4X objective and make sure that that objective is pointing directly down toward the stage. (Failure to do steps 6, 7, and 8 in order can result in the objective hitting the stage, causing breakage!)

9) Once you have prepared your slide, you will place it on the STAGE, securing it between the two metal clips.
10) Locate the STAGE ADJUSTMENT/MOTION knob. Notice that this allows you to move the stage right and left and forward and back. You should try to center the specimen on your slide over the light source with the naked eye using the STAGE ADJUSTMENT knob.

Only after performing all of the steps (1-14) first and in order, do you want to proceed with the instructions here.

15) Once you have your object fully focused at 4X, make sure the object is directly in the center of our point of view. from this point YOU WILL NO LONGER BE USING THE COARSE FOCUS KNOB!
16) Now you can rotate the NOSE-PEICE carefully to ensure that you are going directly to only the NEXT HIGHEST magnification only (this would be the 10X). Skipping over a magnification objective may cause the objective to hit the stage, causing damage!
17) If you have followed the instructions closely, your specimen should be relatively in focus and in your new (smaller) field of view. You may now use the STAGE ADJUSTMENT knob and the FINE FOCUS (NOT THE COARSE FOCUS) to center and focus the object at this new magnification. If you "lose your specimen" in the field of view, you must go down to the 4X objective and start over. "Fishing" for the object with the higher objectives can cause the objective the hit the stage, not to mention that it will be much easier to find the object with the larger field of view of the 4X objective.
18) In order to go to 40X, you will repeat steps 16 and 17 accordingly.

Can You Identify These Parts of The Microscope?

1) Turn off POWER switch.
2) Make sure the stage is all the way toward the bottom (toward the base).
3) Make sure that the 4X objective is pointing down toward the stage.
4) Wrap up and Secure Cord.
5) Carry with 2 hands; one on the base and the other on the body.
6) Be aware of your surrounding and carefully place the scope in the proper place.
7) Make sure you area is left clean.

PARFOCAL
--- Microscopes have a special property, called "being PARFOCAL" which means that once the object is focus and centered using the 4X, when you switch to the next highest objective, your specimen will be relatively centered and in focus. You should only have to make MINOR adjustments to the FINE FOCUS and the STAGE POSITION, in order to view your object at the higher objective. If you have difficulty, you must go back to 4X and recenter and refocus!

The field of view DECREASES as you INCREASE magnification.The amount of light observed through the microscope gets dimmer (is reduced) as you increase magnification.You should notice that the image you see is UP-SIDE-DOWN and REVERSED (the is INVERSION).This means the object will appear to move in the OPPOSITE direct as it is being moved in reality.You should notice that your DEPTH OF FOCUS decreases as magnification INCREASES. This means that with a relatively small movement of the fine focus knob, you could be out of the focal range. For looking at cells, you will notice you will see fewer layers of cells at higher magnifications.You can measure the actual length of your field of view by viewing a ruler or standardized grid with millimeter demarcations using the 10 X objective. count the number of mm in your field of view, then convert to micrometers. (1000um = 1mm).

Dark-field microscopy is used for observing objects that have low contrast.Only light rays scattered by specimen enter objective lens.Specimen appears light against dark background.

Increases contrast and enables observation of more details.

Image courtesy of https://group1micropara.weebly.com/microscope/dark-field-microscopy