`O_(2)` undergoes photochemical dissociation into one normal oxygen atom and one excited oxygen atom. Excited oxygen atom is `1.967 eV` more energetic than normal . The dissociation of `O_(2)` into two normal atoms of oxygen required `498 kJ mol^(-1)`, what is the maximum wavelength effective for photochemical dissociation of `O_(2)`?

O_(2) undergoes photochemical dissocia tion into one normal oxygen atom one oxygen atom 1.967 eV more energetic than normal .The dissociation of O_(2) into two bnormal atoms of oxygen required 498 kJ mol^(-1) what is the maximum wavelength effective for photochemical dissociation of O_(2) ?

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

N_(2) undergoes photochemical dissociation into one normal N- atom and one N- atom having 0.1eV more energy than normal N- atom. The dissociation of N_(2) into two normal atom of N requires 289.5 KJ//mol energy. The maximum wavelength effective for photochemical dissociation of N_(2) in nm is P nm ( 1 eV = 96.5 KJ/mol). Find the value of (P)/(100) .

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 :

Hydrogen when subjected to photon disocation, yieds one normal atom and atom possessing 1.97 eV more energy than normal atom .The bond dissociation energy of hydrogen molecule into normal atom is 103 kcal mol^(-1) . Campate the wavelength of effective photon for photo dissociation of hydrogen molecule in the given case

Oxygen atoms and hydrogen atoms in H_2O_2 are collinear.

In a carbon monoxide molecule, the carbon and the oxygen atoms are separated by a distance 1.2xx10^-10m . The distance of the centre of mass from the carbon atom is

Photochemical dissociation of oxygen result in the production of two oxygen atoms one in the ground state and in the excited state O_(2) overset(hv) to O + O^(*) The maximum wavelength (1) needed for this is 17.4 nm .If the exchation energy O rarr O^(*) is 3.15 xx 10^(-19) J How much energy in kJ mol^(-1) is needed for the dissociation of 1 mole of oxygen into normal atoms in the ground state

One requires 11eV of energy to dissociate a carbon monoxide molecule into carbon and oxygen atoms. The minimum frequency of the appropriate electromagnetic radiation to achieve the dissociation lies in.

One requires 11eV of energy to dissociate a carbon monoxide molecule into carbon and oxygen atoms. The minimum frequency of the appropriate electromagnetic radiation to achieve the dissociation lies in.