Photon having wavelength 310nm is used t...

Photon having wavelength `310nm` is used to break the bond of `A_(2)` molecule having bond energy `28kg mol^(-1)` then `%` of energy of photon converted to the `K.E.` is `[hc=12400 evÅ,1ev=96kJ //mol]`

Similar Questions

Explore conceptually related problems

Photon having wavelength 310 nm is used to break the bond of A_(2) molecule having bond energy 288 kJ mol^(-1) then % of energy of photon converted to the KE is : [hc = 12400 eV"Å" , 1 e V = 96 kJ/mol]

Bond energy of N-N is x kJ "mol"^(-1) . Then bond energy of N-=N is

A photon with a wavelength of 4000A^@ is used to break the iodine molecule, then the % of energy converted to the K.E. of iodine atoms if bond dissociation energy of I_2 molecule is 246.5 kJ/mol

Calculate energy of photon having 6840 Å wavelength (hc=12400 eVÅ)

The approximate energy (kJ mol^(-1)) of hydrogen bonding is

4000 overset(0)(A) photons is used to break the iodine molecule, then the % of energy converted to the K.E of iodine atoms if bond dissociation energy of I_(2) molecule is 246.5 kJ//mol

A photon of 4000 A^o is used to break the iodine molecule, then the % of energy converted to the K.E. of iodine atoms if bond dissociation energy of I_2 molecule is 246.5 kJ/mol is:

A photon of 3000 A^o is used to break the iodine molecule, then the % of energy converted to the K.E. of iodine atoms if bond dissociation energy of I_2 molecule is 255.5 kJ/mol is:

The bond energy (in kJ mol^(-1) ) of C-C single bond is, approximately,

Photon having wavelength `310nm` is used to break the bond of `A_(2)` molecule having bond energy `28kg mol^(-1)` then `%` of energy of photon converted to the `K.E.` is `[hc=12400 evÅ,1ev=96kJ //mol]`

Similar Questions

Recommended Questions