The total magnification of a light microscope with a 40x objective lens is calculated by multiplying the magnification of the objective lens by the magnification of the eyepiece lens. Assuming a standard eyepiece magnification of 10x, the total magnification would be 400x (40x objective lens * 10x eyepiece lens = 400x total magnification).
It would be 50x. To find the magnification, you just have to multiply the number eyepiece and the number objective. So for example, * A 10x eyepiece and a 40x objective would have a magnification of 400x * A 10x eyepiece and a 100x objective would have a magnification of 1,000x
10x magnification means that an object appears 10 times larger than its actual size, while 40x magnification means that the object appears 40 times larger than its actual size. These magnifications are commonly used in microscopes to view objects in greater detail.
A light microscope can typically magnify objects up to 1000 times their original size. This level of magnification allows for the visualization of details down to the cellular level. Beyond this, electron microscopes are used to achieve much higher levels of magnification.
None. A microscope is not need to figure out the mintmark. It is big enough to see. You can however use a magnifying glass to see other details better.
A magnification of at least 400x is typically needed to see protists clearly under a microscope. This level of magnification allows you to observe the details of their structure and movement.
No, the endoplasmic reticulum is too small to be seen at 400x magnification. It is a cellular organelle that is only visible under higher magnifications, typically around 1000x or more using an electron microscope.
The total magnification of the microscope when using the 40x objective depends on the strength of the eye piece lens. Typically a 10x eye piece lens is used in college microscopes this would give 40x10 = 400x magnification.
To find the new field of view at 400X magnification, you would divide the original field of view by the magnification increase factor (which is 10 in this case since you are going from 40X to 400X). So, 6000 um / 10 = 600 um. Therefore, the field of view at 400X magnification would be 600 micrometers.
The total magnification of a light microscope with a 40x objective lens is calculated by multiplying the magnification of the objective lens by the magnification of the eyepiece lens. Assuming a standard eyepiece magnification of 10x, the total magnification would be 400x (40x objective lens * 10x eyepiece lens = 400x total magnification).
No, peroxisomes are generally not visible under standard light microscopy at 400X magnification. They are too small and require higher magnifications and specific staining techniques to be visualized.
The total magnification of a microscope is equal to the magnification of the eyepiece lens multiplied by the magnification of the objective lens. For example, if the eyepiece has a magnification of 10x and the objective lens has a magnification of 40x, the total magnification would be 10x * 40x = 400x.
One can obtain a total magnification of 400x while using an objective lens of 40x. Such a lens should be used along an eyepiece of 10x.
400x
To calculate the total magnification of a compound microscope, you simply multiply the magnification of the eyepiece by the magnification of the objective. For example, if the eyepiece magnifies 10x and the objective magnifies 40x, then the total magnification is 10x * 40x = 400x.
Medium power magnification on a microscope typically ranges from around 100x to 400x. At this magnification level, you can observe more details of the specimen while still maintaining a decent field of view. It is commonly used for observing cellular structures and larger microorganisms in greater detail.
400x gives the smallest field of view. The magnification of the instrument, and the field of view are inversely rational.