Two different first order reactions have rate constants `k_(1) and k_(2)" at "T_(1) (k_(1) gt k_(2))`. If temperature is increased from `T_(1)" to "T_(2)`, then new constants becomes `k_(3) and k_(4)` respectively. Which among the following relations is correct?

Two different first order reactions have rate consants k_(1) and k_(2) "at" T_(1)(k_(1)gtk_(2)) . If temperature is increased form T_(1) "to"T_(2) ,then new consant become k_(3) and k_(4) respeectively. Which among the following relartions is correct

Two springs have their force constant as k_(1) and k_(2) (k_(1) gt k_(2)) . When they are streched by the same force.

The activation energies of two reactions are E_(1) & E_(2) with E_(1)gtE_(2) . If temperature of reacting system is increased from T_(1) (rate constant are k_(1) and k_(2) ) to T_(2) (rate constant are k_(1)^(1) and k_(2)^(1) ) predict which of the following alternative is correct.

If K_(1)= Rate constant at temperature T_(1) and k_(2) rate constant at temperature T_(2) for a first order reaction, then which of the following relation is correct ?

Two springs have their force constant as K_(1) and K_(2)(K_(1)lt K_(2)) . When they are stretched by the same force:

Two springs have force constants k_(1) " and " k_(2) (k_(1) gt k_(2)) . On which spring is more work done, if (i) they are stretched by the same force and (ii) they are stretched by the same amount ?

A chemical reaction was carried out at 300 K and 280 K. The rate constants were found to be k_(1) and k_(2) respectively. Then

Activation energy (E_(a)) and rate constants ( k_(1) and k_(2) ) of a chemical reaction at two different temperatures ( T_(1) and T_(2) ) are related by

Two springs have spring constants k_(1)and k_(2) (k_(1)nek_(2)). Both are extended by same force. If their elastic potential energical are U_(1)and U_(2), then U_(2) is

Two springs have spring constants k_(1)and k_(2) (k_(1)nek_(2)). Both are extended by same force. If their elastic potential energical are U_(1)and U_(2), then U_(1) : U_(2) is