The volume strength of 1 M `H_(2)O_(2)` is : (Molar mass of `H_(2)O_(2) = 34 g mol^(-1)`

The volume strength of g1 M H_(2)O_(2) is : (Molar mass of H_(2)O_(2) = 34 g mol^(-1) )

The volume strength of 2M H_(2)O_(2) is (Molar mass of H_(2)O_(2) = 34 g mol^(-1) )

The volume strength of 1*5 N H_(2)O_(2) solution is

The volume strength of 1.5 N H_(2)O_(2) solution is

A 20 ml solution containing 0.2 g impure H_(2)O_(2) reacts completely with 0.316 g of KMnO_(4) in acidic medium. What would be volume strength of H_(2)O_(2) solution? [Given: Molar mass of H_(2)O_(2)=34 & KMnO_(4)= 158 g/mol]

The strength of 11.2 volume solution of H_(2)O_(2) is: [Given that molar mass of H = 1 g mol^(-1) and O = 16 g mol^(-1) ]

Volume strength of H_(2)O_(2) labelled is 10 vol . What is normality of H_(2)O_(2) ?

Calculate the volume strength of an N/10H_(2)O_(2) solution.

Calculate the number of H_(2)O molecules in 0.06 g of water. [Molar mass of H_(2)O =18 g mol^(-1)]

The strength of H_(2)O_(2) is expressed in many ways like molarity , normality , % strength and volume strengths But out of all these form of strengths , volume strength has great significance for chemical reactions . This decomposition of H_(2)O_(2) is shown as under H_(2)O_(2)(l) to H_(2)O(l) + (1)/(2)O_(2)(g) 'x' volume strength of H_(2)O_(2) means one volume (litre or ml) of H_(2)O_(2) releases x volume (litre or ml) of O_(2) at NTP . 1 litre H_(2)O_(2) release x litre of O_(2) at NTP =(x)/(22.4) moles of O_(2) From the equation , 1 mole of O_(2) produces from 2 moles of H_(2)O_(2) . (x)/(22.4) moles of O_(2) produces from 2xx(x)/(22.4) moles of H_(2)O_(2) =(x)/(11.2) moles of H_(2)O_(2) So, molarity of H_(2)O_(2)=((x)/(11.2))/(1)=(x)/(11.2)M Normality =n-factor xx molarity =2xx(x)/(11.2)=(x)/(5.6) N 30 g Ba(MnO_(4))_(2) sample containing inert impurity is completely reacting with 100 ml of "28 volume" strength of H_(2)O_(2) in acidic medium then what will be the percentage purity of Ba(MnO_(4))_(2) in the sample ? (Ba=137, Mn=55, O=16)