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Ibuprofen is a molecular compound, as it is composed of covalently bonded atoms (carbon, hydrogen, and oxygen). It does not dissociate into ions in solution like ionic compounds.
To find the grams of Ibuprofen, you first need to know its molar mass, which is 206.28 g/mol. Then, you can calculate the grams by multiplying the number of moles (0.525 mol) by the molar mass (206.28 g/mol), which gives you approximately 108.2 grams of Ibuprofen.
The number of moles of carbon in 11,5 g of ibuprofen is 0,725.
The molecular mass of sodium nitrate is 84,9947.
17 g/mol is the molecular mass of ammonia NH3.
molar mass of empirical = 7x12 + 9x1 + 16 = 109 g/mole218.078/109 = 2 so there are 2 empirical formulae in 1 molecular formulaThe molecular formula is therefore C14H18O2
Ibuprofen is a molecular compound, as it is composed of covalently bonded atoms (carbon, hydrogen, and oxygen). It does not dissociate into ions in solution like ionic compounds.
To find the grams of Ibuprofen, you first need to know its molar mass, which is 206.28 g/mol. Then, you can calculate the grams by multiplying the number of moles (0.525 mol) by the molar mass (206.28 g/mol), which gives you approximately 108.2 grams of Ibuprofen.
I assume you mean the molecular mass. Its molecular mass is 86.175
I assume you mean the molecular mass. Its molecular mass is 342.3g/mol
The molecular mass of cytosine is approximately 111.1 grams per mole.
Molecular mass of pentane is 72 u.
The number of moles of carbon in 11,5 g of ibuprofen is 0,725.
The molecular mass of water vapour is 18.01528
The gram molecular mass of hydrogen is 1 gram per mole.
Obtain the molecular mass by determining the m/z value of the molecular ion peak (rightmost in the spectrum).
The molecular mass of sodium chloride is 58,44 (rounded).