The low power objective is typically used for initial focusing and general observation. Placing it in position during storage or transportation helps protect the more delicate high power and oil immersion objectives from potential damage or misalignment.
The concentration of the NaCl solution would be 1.00 g/100 mL = 10 g/L or 10 mg/mL.
A Richter 7.0 earthquake is 1,000 times stronger than a Richter 4.0 earthquake. The Richter scale is logarithmic, so each whole number increase represents a tenfold increase in amplitude and approximately 31.6 times more energy release.
Molar mass of Fe-fumarate is 169.8 g/molAtomic mass of Fe is 55.81 mol of Fe-fumarate is 169.8 g; 55.8 g of that is Fe2+.So, 100 mg of Fe-fumarate will have 100x(55.8/169.8)=32.8 mg of elemental FeQuestion is on ferrous ascorbate but answer is on ferrous fumarate. Confused
Oh, dude, it's like making a fancy cocktail but with salt. So, for 0.1mM, you just take 1 part of the 10mM NaCl and mix it with 9 parts of water. For 0.3mM, it's 3 parts NaCl and 7 parts water. And for 1mM, it's just 1 part NaCl and 9 parts water. Easy peasy, lemon squeezy!
100x the higher the magnification the shorter the working distance
A magnification of 100x typically requires the use of a 100x objective lens on a microscope. Different microscopes may have varying objective lens magnifications, but for a total magnification of 100x, the 100x objective is commonly used.
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The total magnification achieved when using a 100x oil immersion lens with a 10x binocular eyepiece is 1000x (100x objective magnification x 10x eyepiece magnification).
The objective power in this case would be 10X, because it is the magnification produced by the eyepiece alone. The total magnification of 100X is achieved by multiplying the eyepiece magnification (10X) with the objective magnification, which would be 10X in this scenario.
Microscopes, telescopes, slide projectors and magnifying glasses (if appropriately sized) will magnify times 10. The magnification is determined by the type of lens and in some instances, distance.
The magnification of a high power objective lens typically ranges from 40x to 100x.
The total magnification would be 100x. This is because when two lenses are used together, the magnification of each lens is multiplied to find the total magnification. So, 10x magnification from the first lens multiplied by 10x magnification from the second lens gives a total magnification of 100x.
The total magnification of a low power objective (LPO) is typically around 100x, a high power objective (HPO) is around 400x, and an oil immersion objective (OIO) can be up to 1000x. This means an oil immersion objective provides the highest magnification among the three.
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).
The magnification of a microscope is calculated by multiplying the magnification of the objective lens by the magnification of the eyepiece. In this case, if you have a 10x low power objective and a 10x high power objective, the total magnification would be 100x (10x * 10x) for both objectives when used with the same eyepiece magnification.
A magnification of 40x means the object appears 40 times larger than its actual size, while a magnification of 100x means the object appears 100 times larger than its actual size. The higher the magnification, the more details and smaller features of the object can be observed.