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'''Molarity''' (M) is a term used in [[chemistry]] to indicate the concentration of a [[solute]] in a [[solvent]], in units of M = [[mole (chemistry)|moles]]/[[liter]].  For a pure compound with virtually no solvent, molarities are in the range of about 10-18 M.  Chemical solutions typically used in labs are often between 10 millimolar (mM) and 1 molar concentrations.  Solutions of biological samples, containing proteins, enzymes or DNA, are more oftenly used in the nanomolar (10<sup>-9</sup> M) or micromolar (10<sup>-6</sup> M) range, up to about 10 mM.  For a solution containing many molecules, each molecule will have a molarity which is independent of the other components, unless they chemically react over time.  Molarity is calculated by dividing the amount (mass) of the chemical being added into a solution by both its molecular mass (molecular weight MW) and the final volume of the solution.
'''Molarity''' (M) is a term used in [[chemistry]] to indicate the concentration of a [[solute]] in a [[solvent]], in units of M = [[mole (unit)|moles]]/[[liter]].  For a pure compound with virtually no solvent, molarities are in the range of about 10-18 M.  Chemical solutions typically used in labs are often between 10 millimolar (mM) and 1 molar concentrations.  Solutions of biological samples, containing proteins, enzymes or DNA, are more often used in the nanomolar (10<sup>-9</sup> M) or micromolar (10<sup>-6</sup> M) range, up to about 10 mM.  For a solution containing many molecules, each molecule will have a molarity which is independent of the other components, unless they chemically react over time.  Molarity is calculated by dividing the amount (mass) of the chemical being added into a solution by both its molecular mass (molecular weight MW) and the final volume of the solution.




:<math> M =  \frac{moles}{liter} = \frac{m}{MW*V}</math>
:<math> M =  \frac{moles}{liter} = \frac{m}{MW \times V} </math>
   
   
where
where
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:''V'' = final volume of the solution
:''V'' = final volume of the solution
== Relation to normality ==
A related concentration unit, [[normality]] (N), is often more convenient when one is dealing with [[acid]]-[[base]] reactions, because a 1 N solution of any acid will always neutralize a 1 N solution of any base.  Normality is a multiple of molarity.
:<math> \mathbf{N} = \mathbf{n} \times \mathbf{M} </math>
where ''n'' is an integer. 
For a monoprotic acid, 1M = 1N, while for diprotic and triprotic acids 1M = 2N and 1M = 3N, respectively.[[Category:Suggestion Bot Tag]]

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Molarity (M) is a term used in chemistry to indicate the concentration of a solute in a solvent, in units of M = moles/liter. For a pure compound with virtually no solvent, molarities are in the range of about 10-18 M. Chemical solutions typically used in labs are often between 10 millimolar (mM) and 1 molar concentrations. Solutions of biological samples, containing proteins, enzymes or DNA, are more often used in the nanomolar (10-9 M) or micromolar (10-6 M) range, up to about 10 mM. For a solution containing many molecules, each molecule will have a molarity which is independent of the other components, unless they chemically react over time. Molarity is calculated by dividing the amount (mass) of the chemical being added into a solution by both its molecular mass (molecular weight MW) and the final volume of the solution.


where

m = mass of chemical added, in grams
MW = molecular weight (mass), in grams/mole
V = final volume of the solution

Relation to normality

A related concentration unit, normality (N), is often more convenient when one is dealing with acid-base reactions, because a 1 N solution of any acid will always neutralize a 1 N solution of any base. Normality is a multiple of molarity.

where n is an integer.

For a monoprotic acid, 1M = 1N, while for diprotic and triprotic acids 1M = 2N and 1M = 3N, respectively.