Formation of `SO_(3)` by `SO_(2)` and `O_(2)` is favoured by `:-`

The formation of SO_(3) from SO_(2) and O_(2) takes place in the following steps : (i) SO_(2)+2NO_(2) to 2SO_(3)+2NO (ii) 2NO +O_(2) to 2NO_(2)

Platinised asbestos helps in the formation of SO_(3) from SO_(2) and O_(2) . But, if even a small amount of As_(2)O_(3) is present the platinised asbestos does not help in the formation of SO_(3), As_(2)O_(3) acts here as a//an .

Apply the law of mass action to the following equilibria : (i) Formation of SO_(3) from SO_(2) and O_(2) (ii) Formation of NO_(2) from nitric oxide and oxygen

The reaction 2SO_(2)+2O_(2)hArr 2SO_(3) will be favoured by

The oxidation of SO_(2) by O_(2) to SO_(3) is an exothermic reaction . The yield of SO_(2) will be maximum if

In the formation of SO_3 by : 2 SO_2 + O_2 overset (NO) (rarr) 2 SO_3 , the catalytic action of NO is evidenced by the formation of :

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

A mixture of SO_(3), SO_(2) and O_(2) gases is maintained in a 10 L flask at a temperature at which the equilibrium constant for the reaction is 100 : 2SO_(2)(g)+O_(2)(g)hArr2SO_(3)(g) a. If the number of moles of SO_(2) and SO_(3) in the flask are equal. How many moles of O_(2) are present? b. If the number of moles of SO_(3) in flask is twice the number of moles of SO_(2) , how many moles of oxygen are present?