Yes, you can see the ER at 400x magnification because of its size of the passageways. In a encyclopedia, it sates that the size of its pasage ways and its job allow it to bee seen at this magnification.
The magnification needed to see cells clearly under a microscope is typically around 400x to 1000x.
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.
Sperm are typically viewed under a microscope at a magnification of around 400x to 1000x. This level of magnification is necessary because sperm cells are very small, usually measuring about 5-6 micrometers in length.
In microbiology, the most commonly used ocular is the 10x magnification ocular. This ocular is typically paired with a 40x objective lens to provide a total magnification of 400x, which is commonly used for observing bacterial and fungal structures.
The total power of magnification refers to how many times bigger than actual size you are viewing the specimen with a microscope. It is measure by multiplying the magnification of the eye piece by the magnification of the objective lens you are using. For example, most eye pieces magnify by 10X. So, if you are viewing a specimen with the 4X objective lens, you are actually seeing the specimen 40 times larger than normal. (10X * 4X)
Yes, with a 400X magnification, you should be able to see crystals in fine detail including their structure, shape, and any impurities present. This level of magnification is commonly used in crystallography and mineralogy studies to analyze crystal properties.
The magnification needed to see cells clearly under a microscope is typically around 400x to 1000x.
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.
There are a number of objectives on the nose piece, usually there are three of them. You can either look at those, to see if they have the magnifying power printed on it, or you can read the instructions, if they came with your microscope. Average microscopes usually have a maximum of 200 or 400x magnifying power. Note: Microscopes have about 3 different magnifying powers. Most are 40x, 100x, and 200 to 400x.
Sperm are typically viewed under a microscope at a magnification of around 400x to 1000x. This level of magnification is necessary because sperm cells are very small, usually measuring about 5-6 micrometers in length.
Volvox can typically be seen at a magnification of around 40-100x under a standard light microscope. Specialized microscopes, such as phase contrast or dark-field microscopes, may be able to provide clearer images at lower magnifications.
Multiply the magnification of the ocular and objective lenses. For an example, an ocular lense with mag 10X and an objective lense with mag 40X would result in a total magnification of 400X.
In microbiology, the most commonly used ocular is the 10x magnification ocular. This ocular is typically paired with a 40x objective lens to provide a total magnification of 400x, which is commonly used for observing bacterial and fungal structures.
Magnification and resolution are both measures of the ability to distinguish fine details in an image. Higher magnification allows for larger images, while higher resolution allows for clearer, more detailed images. Both factors are important in microscopy and imaging techniques for observing small structures.
with your image resolution? Nothing happens it remains the same till you change it in Image Size dialog. Image > Image Size.. Magnification is for your convenience to see enlarged image nothing really happens to actual resolution of original image.
At 4000x magnification, you could observe details such as the intricate structures of individual cells, including organelles like mitochondria and the endoplasmic reticulum, which are not visible at lower magnifications. You might also see the fine details of cellular processes, such as mitosis, or the surface features of small organisms like bacteria or protozoa. Additionally, this level of magnification could reveal the texture of materials at a nanoscale, such as fibers in a tissue sample or the arrangement of molecules in a crystal.
We had to increase the magnification of the microscope in order to see the cells clearly.