Ewab ko! HAHAHHAHAH.
~BOOM. mica Presto
When moving the slides in different directions of the microscope, you may notice changes in the area of the specimen being observed, such as different cellular structures coming into view or shifting out of focus. This can help with examining different regions of the specimen and obtaining a more comprehensive understanding of its features. The movement can also provide a closer look at specific details or help in locating and identifying specific structures within the specimen.
Yes. The velocity changes when the direction of motion changes, because the definition of 'velocity' is 'speed and the direction'. If either speed or direction changes, then we say the velocity has changed. Notice that if the direction changes, then the velocity changes even if the speed doesn't. "Velocity" is not just a bigger word that you use for 'speed' when you want to sound smart. They mean different things.
As you open the diaphragm under the stage, you allow more light to pass through the specimen. This can improve depth of focus but, it can also cause the image to become more washed out.
A characteristic of something you are able to observe is that you are actually able to see it. It is also imperative that you would be able to notice changes in its appearance or behavior.
-- Changing the frequency/wavelength has no effect on the speed. (Notice that all electromagnetic waves, from wavelengths of perhaps 10-19 meters to perhaps 1,000 kilometers, travel with the same speed.) (Also notice that if the baritone sax plays a note together with the female vocalist, then you hear them at the same time, no matter how far from the stage you're seated.) -- Changing the frequency causes the wavelength to change, by the same factor in the opposite direction. -- Changing the speed causes the wavelength to change, by the same factor in the same direction.
You should notice that the image in the microscope moves in the opposite direction to the movement of the slide. For example, if the specimen slide is moved top to bottom, the image seen moves from bottom to top. This can be very confusing.
When moving the slides in different directions of the microscope, you may notice changes in the area of the specimen being observed, such as different cellular structures coming into view or shifting out of focus. This can help with examining different regions of the specimen and obtaining a more comprehensive understanding of its features. The movement can also provide a closer look at specific details or help in locating and identifying specific structures within the specimen.
You should notice that the image in the microscope moves in the opposite direction to the movement of the slide. For example, if the specimen slide is moved top to bottom, the image seen moves from bottom to top. This can be very confusing.
You should notice that the image in the microscope moves in the opposite direction to the movement of the slide. For example, if the specimen slide is moved top to bottom, the image seen moves from bottom to top. This can be very confusing.
As you change the diaphragm by opening it under the stage, you are allowing more light to pass through the specimen. This can improve depth of focus but, it can also cause the image to become more washed out.
A phase-contrast microscope (or phase-difference microscope or phase microscope) allows better viewing of clear specimens that usually need to be stained before you can make out the various parts. Staining is a time consuming process and kills the cells being viewed. With a phase-contrast microscope, living cells can be studied as they go through the cell division cycle.HOW IT WORKSAs light goes through a transparent specimen, there may not be anything interesting to see. However, the light undergoes phase changes as it passes through the different parts of the specimen. Unfortunately, the human eye does not notice phase changes. A phase-contrast microscope converts these unnoticed phase changes into differences in brightness, which the human eye sees very well. The darker and lighter parts of the specimen make it very visible.This also works on reflected light microscopes.
big stomach.
Kids begin to have puberty and they begin to notice changes in there body.
Direct evidence are visible noticable changes. Indirect evidence is when you might not see the action happen but you do notice the results
If you want to notice your girlfriends bangs, you need to look at them. If you don't pay attention you won't notice any changes.
A phase-contrast microscope (or phase-difference microscope or phase microscope) allows better viewing of clear specimens that usually need to be stained before you can make out the various parts. Staining is a time consuming process and kills the cells being viewed. With a phase-contrast microscope, living cells can be studied as they go through the cell division cycle.HOW IT WORKSAs light goes through a transparent specimen, there may not be anything interesting to see. However, the light undergoes phase changes as it passes through the different parts of the specimen. Unfortunately, the human eye does not notice phase changes. A phase-contrast microscope converts these unnoticed phase changes into differences in brightness, which the human eye sees very well. The darker and lighter parts of the specimen make it very visible.This also works on reflected light microscopes.
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