It is of 45x objective and 10x of eyepiece total 450x
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.
If you are using the oil immersion objective on a microscope, you must use oil to increase the resolution of the lens. These lens are used at very high magnification.
Immersion oil is only required when using a light manuscript at 1000 times magnification (10x from occular lens and 100x from objective lens). At 1000x magnification the image will have poor resolution (loook fuzzy) without the use of immersion oil. This is because the cover slip on the sample and air have different refractory indexes. The light scatter that occurs during the transition from glass to air is noticable at such a high magnification. Immersion oil has a refractive index very similar to the cover slip, thus reducing the light scatter as the light passes from the sample to the objective lens.
The total magnification would be 750X (100X objective multiplied by 7.5X eyepiece). Oil immersion objectives are specifically designed for use with immersion oil to minimize light refraction and increase resolution when viewing specimens with high magnification.
To increase the magnification of a refracting telescope without decreasing its light-gathering power, you can use a longer focal length eyepiece. This allows for higher magnification while maintaining the same aperture size, which ensures that the telescope continues to gather light effectively. Additionally, you could also employ a focal extender or a Barlow lens, which increases magnification without affecting the aperture's ability to collect light.
The use of an oil lens in a microscope enhances magnification and resolution by reducing light refraction and increasing the numerical aperture, allowing for clearer and more detailed images to be seen.
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.
If you are using the oil immersion objective on a microscope, you must use oil to increase the resolution of the lens. These lens are used at very high magnification.
Immersion oil is only required when using a light manuscript at 1000 times magnification (10x from occular lens and 100x from objective lens). At 1000x magnification the image will have poor resolution (loook fuzzy) without the use of immersion oil. This is because the cover slip on the sample and air have different refractory indexes. The light scatter that occurs during the transition from glass to air is noticable at such a high magnification. Immersion oil has a refractive index very similar to the cover slip, thus reducing the light scatter as the light passes from the sample to the objective lens.
The total magnification would be 750X (100X objective multiplied by 7.5X eyepiece). Oil immersion objectives are specifically designed for use with immersion oil to minimize light refraction and increase resolution when viewing specimens with high magnification.
it's impossible to just use the eyepiece without an objective lens, but the eyepiece alone is 10x.
You will need to use magnification in order to identify the cells on the slides.
950
To increase the magnification of a refracting telescope without decreasing its light-gathering power, you can use a longer focal length eyepiece. This allows for higher magnification while maintaining the same aperture size, which ensures that the telescope continues to gather light effectively. Additionally, you could also employ a focal extender or a Barlow lens, which increases magnification without affecting the aperture's ability to collect light.
We had to increase the magnification of the microscope in order to see the cells clearly.
you can't
To achieve a total magnification of 100x, you would use a 10x ocular lens (eyepiece) with a 10x objective lens. The total magnification is calculated by multiplying the magnification of the ocular lens (10x) by the magnification of the objective lens (10x).