[" (4) "2.66Lmin^(-1)" at STP "],[" Two ...

[" (4) "2.66Lmin^(-1)" at STP "],[" Two reactions "R_(1)" and "R_(2)" have identical pre- "],[" exponential factors.Activation energy of "R_(1)],[" exceeds that of "R_(2)" by "10kJmol^(-1)" .If "k_(1)" and "R_(2)],[" are rate constants for reactions "R_(1)" and "R_(2)],[" respectively at "300K" ,then "ln(k_(2)/k_(1))" is equal to :- "],[(R=8.314smol^(-1)K^(-1))quad " [JERMain "-2017]],[[" (1) "8," (2) "12," (3) "6," (4) "4]]

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Two reactions , R_(1) and R_(2) have identical pre-exponential factors . Activation energy of R_(1) exceeds that of R_(2) by 10"kJ.mol"^(-1) . If k_(1) and k_(2) are rate constants for reaction R_(1) and R_(2) respectively at 300K, then In (K_(2)//k_(1)) is equal to (R=8.314"J.mol"^(-1).k^(-1)) -

Two reactions R_(1) and R_(2) have identical pre - exponential factors. Activations enery of R_(1) exceeds that of R_(2) by 10 kJ mol_(-1) . If k_(1) and k_(2) are rate constants for rate constants for reactions R_(1) and R_(2) respectively at 300k , then In (k_(2)/k_(1)) is equal to (R=8.314 J mol^(-1)K^(-1))

Two reactions R_(2) and R_(2) have identical pre - exponential factors. Activations enery of R_(1) exceeds that of R_(2) by 10 kJ mol_(-1) . If k_(1) and k_(2) are rate constants for rate constants for reactions R_(1) and R_(2) respectively at 300k , then In (k_(2)/k_(1)) is equal to (R=8.314 J mol^(-1)K^(-1))

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