Ozone in the upper atmoshphere absorbs ultraviolet radiation which induces the following chemical reaction
`O_(3)(g)rightarrowO_(2)(g)+O(g)`
`O_(2)` produced in the above photochemical dissociation undergoes further dissociation into one normal oxygen atom (O) and more energetic oxygen atom `O**`.
`O_(2)(g) rightarrowO+O**`
`(O**)` has 1 eV more energy than(O) and normal dissociation energy of `O_(2)` is 480 kJ `"mol"^(-1)`.
[1 eV/Photon =96 kJ `"mol"^(-1)`]
What is the maximum wavelength effective for the photochemical dissociation of `O_(2)` molecule

Ozone in the upper atmoshphere absorbs ultraviolet radiation which induces the following chemical reaction O_(3)(g)rightarrowO_(2)(g)+O(g) O_(2) produced in the above photochemical dissociation undergoes further dissociation into one normal oxygen atom (O) and more energetic oxygen atom O** . O_(2)(g) rightarrowO+O** (O**) has 1 eV more energy than(O) and normal dissociation energy of O_(2) is 480 kJ "mol"^(-1) . [1 eV/Photon =96 kJ "mol"^(-1) ] If dissociation of O_(3) into O_(2) and O requires 400kJ mol^(-1) and O_(2) produced in this reaction is further dissociated to O and O** then the total energy required to for the dissociation of O_(3) into O and O** is :

Balance the following equation : CH_4(g) +O_2(g) rarr CO_2 (g)+H_2O(l)

For the reactions : C(s) + O_(2) (g) to CO_(2) (g)

Write the equilibrium constant expression for the following reactions. CH_(4)(g) + 2O_(2)(g) hArr CO_(2)(g) + 2H_(2)O(l)

Consider the following reactions: C(s)+O_(2)(g)toCO_(2)(g)+x " kJ" CO(g)+(1)/(2)O_(2)(g)toCO_(2)(g)+y" kJ" The heat formation of CO(g) is :

Balance the following chemical equations and identify the type of chemical reaction: H_2O_2(l) rarr H_2O(l)+O_2(g)

identify the type of reaction in the followng example 2H_2(g) + O_2(g) rarr 2H_2O(l)

What is the equivalent mass of O_2 in the following reaction , H_2O+1/2O_2+2e^(-)to2OH^(-) ?

The initial concentration of N_2O_5 in the following first order reaction N_2O_5(g) rarr 2 NO_2(g) + 1/2O_2 (g) was 1.24 x 10^(-2) mol L^(-1) Calculated the rate constant of the reaction at 318 K.