`Psi_(r) =k_(1) e^(-r//k_(2))(r^(2)-5k_(3) r+6K_(3)^(2))`
For the above orbital match the column-I with column-II (assuming `,k_(3)=1`)

Psi_((r)) = ke^(-r//k_(1)) dot" r^(2) (r^(2) - k_(2)r + k_(3)) . If the orbital has no nodal plane , then , orbital can be :

In a triangle ABC, if (r_(1)+r_(2))(r_(2)+r_(3))(r_(3)+r_(1))4RK then k=

For the consecutive unimolecular-type first-order reaction A overset(k_(1))rarr R overset(k_(2))rarr S , the concentration of component R, C_( R) at any time t is given by - C_(R ) = C_(OA)K_(1)[e^(-k_(1)t)/((k_(2)-k_(1))) +e^(-k_(2)t)/((k_(1)-k_(2)))] if C_(A) = C_(AO), C_(R ) = C_(RO) = 0 at t = 0 The time at which the maximum concentration of R occurs is -

60.A consecutive reaction occurs with two equilibria which co-exist together P(k_(1))/(k_(2) Q (k_(3))/(k_(4) R Where k_(1) , k_(2) , k_(3) and k_(4) are rate constants.Then the equilibrium constant for the reaction P harr R is (1) (k_(1)*k_(2)) / (k_(3)*k_(4) ) (2) (k_(1)*k_(4)) / (k_(2)k_(3) ) (3) k_(1) * k_(2) * k_(3)*k_(4) (4) (k_(1)*k_(3)) / (k_(2)k_(4)) ]]

If (n-1)C_(r)=(k^(2)-3)nC_(r+1), then k belong to

If C((n-1),r)=(k^(2)-3)C(n,(r+1)) then range of k is

sqrt((9^((r + (I)/4)) sqrt(3.3^(-r)))/(3.sqrt(3^(-r)))) = k , then the value of k is