A sample of `NaClO_(3)` is converted by heat to `NaCl` with a loss of `0.16g`of oxygen. The residue is dissolved in water and precipitated as `AgCl`. The mass of `AgCl` (in g) obtained will be: (Given : Molar mass of `AgCl = 143.5 g mol^(-1)`)

14.625mg of NaCl is treated with AgNO_(3)(aq) .The mass of AgCl obtained as ppt is ( Ag=108g//mol )

A solution is prepared by adding 10 g of NaCl to 18 g of water. Calculate mole fraction of NaCl. (Molar mass of NaCl = 58.5 g).

If 8g of a non-electrolyte solute is dissolved in 114g of n-octane to educe its vapour pressure to 80% , the molar mass of the solute is [ given molar mass of n-octane is 114g mol^(-1) ]

The specific conductance of saturated solution os silver chloride is k(ohm^(-1)cm^(-1)) . The limiting ionic conductance of Ag^(+) and Cl^(-) ions are x and y respectively. The solubility of AgCl in "gram liter"^(-1) is : (Molar mass of AgCl=143.5"g mol"^(-1) )

5.85 g NaCl is dissolved in 500 ml of water. The molarity is

A 1.0g sample of a pure organic compound cotaining chlorine is fused with Na_(2)O_(2) to convert chlorine to NaCl. The sample is then dissolved in water, and the chloride precipitated with AgNO_(3) , giving 1.96 g of AgCl. If the molecular mass of organic compound is 147, how many chlorine does each molecule contain ?

A solution containing 2.675 g of CoCl_(3).6NH_(3) (molar mass = 267.5 g mol^(-1) is passed through a cation exchanger. The chloride ions obtained in solution are treated with excess of AgNO_(3) to give 4.78 g of AgCl (molar mass = 143.5 g mol^(-1) ). The formula of the complex is (At.mass of Ag = 108 u ) .

A solution containing 2.675 g of CoCl_(3).6NH_(3) (molar mass = 267.5 g mol^(-1) ) is passed through a cation exchanger. The chloride ions obtained is solution were treated with excess of AgNO_(3) to give 4.73 g of AgCl (molar mass = 143.5 g mol^(-1) ). The formula of the complex is (At. mass of Ag = 108 u)