By using the formula V1 x C1 = V2 x C2
Taking V1= 100 mL; C1= 1.00M; C2= 0.31M
V2 = volume (in mL) of 0.31M
V2 = V1 x N1 / N2 = 100x1.000/0.31= 322.6 mL
So you have to fill 100 mL UP TO 322.6 mL (total volume)with about (or somewhat more) than 322-100 = 222 mL (volume to add)
2.0 M
Molarity is moles/liter, so in order to find the moles of a substance in a given volume, simply multiply molarity with volume (in liters). n=M*V
5.85gms/500cc
you can prepare 20nM sodium phosphate buffer pH7.0. calculate mass of enzyme and dilute in volume buffer to reach concentration you want. good luck
0.9% w/v (weight per volume, otherwise known as grams per 100ml) sodium chloride is NaCl abbreviated
This depends on: - the volume of the drop - the concentration of sodium chloride solution
1. A volume of powdered sodium chloride.2. A volume of water solution of sodium chloride with a non-specified concentration in this case..
Density=Mass/Volume
It depends on the volume, if we consider 1 liter of the solution 500 mg of sodium chloride is needed.
The concentration is 50,6 g/L.
5.8g of sodium chloride would need to be added to the blood to bring the sodium ion concentration up to 0.140m with no change in blood volume. This is also known as the Ionic strength.
The meaning of concentration is the amount of material in a defined mass or volume as liter, kilogram, cubic meter, 100 mL etc.; as an example sea water contain 30 g/L sodium chloride.
Sodium chloride solution, dextrose solution, ringer's solution and lactated ringer's solution are all common large volume parenteral products.
The concentration of a solution is basically how strong the solution is.
This depends on the concentration of sodium chloride, volume of the solution, beaker, source of heat.
There is twice the change in colligative properties in the sodium chloride solution than in the glucose solution.
2.0 M