The rate of formation of `SO_(3)` in the reaction `2SO_(2)+O_(2)to2SO_(3)` is 100 g `"min"^(-1)` Hence rate of disappearance of `O_(2)` is

In the reaction 2NO+O_(2)to2NO_(2) , if the rate of disappearance of O_(2) is 16 "gm min"^(-1) , then the rate of appearance of NO_(2) is

For the reaction N_(2)+3H_(2)to2NH_(3) , the rate of disappearance of H_(2) is "0.01 mol lit"^(-1)"min"^(-1) . The rate of appearance of NH_(3) would be

In the reversible reaction 2NO_(2) underset(k_(2))overset(k_(1))(hArr)N_(2)O_(4) the rate of disappearance of NO_(2) is equal to

In the formation of sulphur trioxide by the contact process, 2SO_(2(g))+O_(2(g))harr2SO_(3(g)) The rate of reaction is expressed as -(d[O_(2)])/(dt)=2.5xx10^(-4)" M sec"^(-1) . The rate of disappearance ("in mol L s"^(-1)) of SO_(2) will be

A mixture of SO_(2),SO_(3) and O_(2) gases are maintained at equilibrium in 10 litre flask at a temperature at which K_(c) for the reaction 2SO_(2)(g)+O_(2)(g)hArr2SO_(3)(g) is 100. At equilibrium. a. If no of moles of SO_(3) and SO_(2) is flask are same, how many moles of O_(2) are present. b. If no. of moles of SO_(3) in flask is twice the no. of moles SO_(2) how many moles of O_(2) are present.

SO_(2) reacts with O_(2) as follows 2SO_(2) +O_(2)to2SO_(3) , the rate of disappearance of SO_(2) is 2.4xx10^(-4) mole "lit"^(-1)"min"^(-1) . Then

SO_(2) reacts with O_(2) as follows 2SO_(2) +O_(2)to2SO_(3) , the rate of disappearance of SO_(2) is 2.4xx10^(-4) mole "lit"^(-1)"min"^(-1) . Then