In chemistry instead mass in kg it would be nice to deal the quantity in moles. Hence molar specific heat is best fit.
No. Specific volume is the inverse of density. Molar volume specific volume divided by mols. (i.e. g/(mLxMols)
Molar solutions are defined as 1 mole of a compound dissoved in a one liter solution. Molar solutions are used in pharmacology making solutions and dilutions of specific compounds.
A 10-fold molar ratio means that there are 10 times as many moles of one substance compared to some other substance.
molar conductivity involves concentration of electrolyte also....but electrolytic conductivity doesn't
The molar heat of uranium is 27.665 J/mol.K.
The answer is simple it's one/1
Specific heat is the heat capacity divided by the heat capacity of water, which makes it dimensionless. To obtain molar heat capacity from specific heat for a material of interest, simply multiply the specific heat by the heat capacity of water per gram [1 cal/(g*C)]and multiply by the molecular weight of the substance of interest. For example, to obtain the molar heat capacity of iron Specific heat of iron = 0.15 (note there are no units) Molar heat capacity of iron = 0.15*1 cal/(g*C)*55.85 g /gmole = 8.378 cal/(gmole*C)
Molar heat capacity of liquid water = 75.3538 Molar heat capacity = molar mass x specific heat
The Stoichiometry of molar concentration follows this simple formula: Mol = Volume (dm³) × Molar Concentration (mol/dm³) Hence: Molar Concentration (mol/dm³) = Number of moles (mol)/ Volume (dm³)
Each compound has a specific molar mass; no conversion.
The molar heat capacity of selenium is 25,363 J/mol.K.
This value is 91,12 J/mol.K.