0.5 mol of `H_(2)SO_(4)` is mixed with 0.2 mol of `Ca(OH)_(2)`. The maximum number of moles of `CaSO_(4)` formed is

0.5 mole of H_(2)SO_(4) is mixed with 0.2 mole of Ca(OH)_(2) . The maximum number of mole of CaSO_(4) formed is:

If 0.5 mol of CaBr_(2) is mixed with 0.2 mol of K_(3) PO_(4) , the maximum nubmer of moles of Ca_(3) (PO_(4))_(2) that can be formed is: a. 0.1 b. 0.2 c. 0.5 d.0.7

If 0.50 mol of BaCl_(2) is mixed with 0.20 mol of Na_(3)PO_(4) , the maximum number of moles of Ba_(3)(PO_(4))_(2) that can be formed is

If 0.5 mole of BaCl_(2) mixed with 0.20 mole of Na_(3) PO_(4) the maximum number of moles of Ba_(3)(PO)_(2) then can be formed is

If 0.5 mole of BaCl_(2) is mixed with 0.20 mole of Na_(3)PO_(4) , the maximum number of Ba_(3)(PO_(4))_(2) that can be formed is :

50ml 0.2 M H_(2)SO_(4) is mixed with 50ml 0.3M H_(2)SO_(4) . Find molarity of final solution .

30 gm H_(2)SO_(4) is mixed with 20 gram SO_(3) to form mixture Find mole fraction of SO_(3)

40ml 0.2 M H_(2)SO_(4) is mixed with 50ml 0.3M H_(2)SO_(4) . Find molarity of final solution .

Calculate number of moles in 392 g of H_(2)SO_(4) ?

1 mol of N_(2) is mixed with 3 mol of H_(2) in a litre container. If 50% of N_(2) is converted into ammonia by the reaction N_(2)(g)+3H_(2)(g) hArr 2NH_(3)(g) , then the total number of moles of gas at the equilibrium are