For the first order reaction `A rarr B +C` , carried out at `27^(@)` C . If `3.8 xx 10^(-16)%` of the reactant molecules exists in the activated state , the `E_(a)` (activation energy) of the reaction is:

For the first order reaction Ato product. When the concentration of A is 2.5xx10^(-2) M the activation energy is 20K. Cal/mole. If the conc. of [A] is doubled, at same temperature the activation energy becomes equal to

A first order reaction has a rate constatn 1.15 xx10^(-3) s ^(-1). How long will 5 g of this reactant take to reduce to 3 g ?

A first order reaction is carried out with an initial concentration of 10 mol per litre an 80% of the reactant changes into the product in 10 sec. Now if the same reaction is carried out with an initial concentration of 5 mol per litre. The percentage of the reactant changing to the product in 10 sec is:

The Delta H value for the reaction, H_(2) + Cl_(2) to 2HCl is - 44.12 Kcal If E_(1) is the activation energy of the reactants and E, is the activation energy of the products, for the above reaction.

A hydrogenation reaction is carried out at 500 K. If the same reaction is carried out in the presence of a catalyst at the same rate with same frequency factor, the temperature required is 400 K. What is the activation energy of the eaction. If the catalyst lowers the activation energy barrier by 16 KJ/mol?

A first order reaction has rate constant 1.15xx10^(-1)s^(-1) . How long will 10 grams of this reactant take to reduce 6 grams ?

A first order reaction is 50% complete in min at 27^(@)C ?and 10 min at 47^(@)C . Calculate the rate constant and activation energy at 27^(@)C .

If the half lives of the first order reaction at 350 K and 300 K are 2 and 20 seconds respectively the activation energy of the reaction in kj "mol"^(-1) is

A reaction proceeds 5 times more at 60^(@)C , as it does at 30^(@)C . Calculate the energy of activation.