0.037g of an alcohol, R-OH was added to `CH_(3)MgBr` and the gas evolved measured 11.2 mL at STP. The Molecular mass of R-OH will be .

i. 0.21 gm of but-3-yn-2-ol is treated with excess of C_(2)H_(5) MgBr at standard condition. The volume of gas evolved is: (a) 134.4 ml, (b) 146.4 ml (c) 67.2 ml, (d) 73.2 ml ii. 0.46 gm of a compound with molecular mass of 92 gm gave 336 ml of a gas at STP when treated with excess of CH_(3) MgI. The number of moles in the compound is: (a) 0.1 , (b) 2 (c) 3, (d) 4 iii. The treatement of CH_(3)OH with CH_(3)Mgl releases 1.04 ml of a gas at STP. The mass of CH_(3)OH added is: (a) 1.49 mg, (b) 2.98 mg (c) 3.71 mg, (d) 4047 mg iv. The addition of 4.12 mg of an unknown alcohol, ROH, to CH_(3)Mgl releases 1.56 ml of a gas at STP. The molar mass of alcohol is: (a) 32 gm mol^(-1) , (b) 46 gm mol^(-1) (c) 59 gm mol^(-1) , (d) 74 gm mol^(-1) v. Teh sample of 1.79 mg of a compound of molar mass 90 gm mol^(-1) when treated with CH_(3)Mgl releases 1.34 mol of a gas at STP. The number of moles of active hydrogen in the molecule is: (a) 1 , (b) 2 (c) 3 , (d) 4

0.2 g of a primary aliphatic amine, on treatment with nitrous acid gave 61.36 ml of N_2 gas at STP. The molecular mass of the amine will be:

240 mL of a dry gas measured at 27°C and 750 mm pressure weighed 0.64 g. What is the molecular mass of the gas ?

In Victor Meyers method, 0.2 g of an organic substance displaced 56 mL of air at STP.The molecular mass of the compound is

0.40 g of an organic compound (A), (M.F.-C_(5)H_(8)O) reacts with x mole of CH_(3)MgBr to liberate 224 mL of a gas at STP. With excess of H_(2) , (A) gives pentan-1-ol. The correct structure of (A) is :

In Victor Meyer's experiment, 0.6 g of a volatile substance displaced 112 mL of air at S.T.P. Find the molecular mass of the substance.

The volume occupied by 0.32 g of a gas at S.T.R is 224 mL. Calculate the molecular mass of the gas.