`k_(34^(@)):k_(35^(@)) lt 1`, then

If inte^(x)/(x^(n))dx and -e^(x)/(k_(1)x^(n-1))+1/(k_(2)-1)I_(n-1) , then (k_(2)-k_(1)) is equal to:

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.

For the reaction of I, II and III orders, k_(1) = k_(2) = k_(3) when concentrations are expressed in mole L^(-1) . What will be the relation in k_(1), k_(2), k_(3) , if the concentration are expressed in mol mL^(-1) ?

If I_(n) = |(1,k,k),(2n,k^(2) + k + 1,k^(2) + k),(2n -1,k^(2) ,k^(2) + k +1)| and sum_(n=1)^(k) I_(n) = 72 , then k =

The order of the differential equation of the family of curves y=k_(1)2^(k_(2)x)+k_(3)3^(x+k_(4)) is (where, k_(1),k_(2), k_(3), k_(4) are arbitrary constants)

A reaction takes place in theee steps: the rate constant are k_(1), k_(2), and k_(3) . The overall rate constant k=k_(1)k_(3)//k_(2) . If the energies of activation are 40,30, and 20 KJ mol^(-1) , the overall energy of activation is (assuming A to be constant for all)

A reaction takes place in theee steps: the rate constant are k_(1), k_(2), and k_(3) . The overall rate constant k=k_(1)k_(3)//k_(2) . If the energies of activation are 40,30, and 20 KJ mol^(-1) , the overall energy of activation is (assuming A to be constant for all)

If k gt 1, |z_(1)| lt k and |(k-z_(1)barz_(2))/(z_(1)-kz_(2))|=1 , then

If the ionic radii of each K^(+) and F^(-) are 1.34Å , then tha atomic radii of K and F will be respectively:

If the solution set of |x-k| lt 2 is a subset of the solution of the inequality (2x-1)/(x+2) lt 1 , then the number of possible integral value(s) of k is/ are :