For a hypotherical elementary reaction where `k_1/k_2=1/2`
Initailly only 2 moles of A are present.
The total number of moles A,B and C at the end of 50% reaction are :

For a hypotherical elementary reaction where k_1/k_2=1/2 Initailly only 2 moles of A are present. The sum of mole of (B) are ( C) at end of reaction is :

For a hypotherical elementary reaction where k_1/k_2=1/2 Initailly only 2 moles of A are present. Number of moles of B are , if reactions gets 50 % completed :

Rate law for the elementary reaction 2AB to^(k_1) A_2+B_2 will be:

In the reaction A + B hArr C + D, 4 moles of A react with 4 moles of B and form 2 moles each of C and D. The value of Ke for the reaction is

14 moles of A and 20 moles of B, 8 moles of C is formed in the following reaction 3A+4Brarr2C then.

For the following elementary first order reaction: If k_(2)=2k_(1) , then % of B in overall product is:

9 moles of "D" and 14 moles of E are allowed to react in a closed vessel according to given reactions. Calculate number of moles of B formed in the end of reaction, if 4 moles of G are present in reaction vessel. (percentage yield of reaction is mentioned in the reaction) Step -1 3D+4E 80%rarr5C+A Step-2 3C+5G 50%rarr 6B+F

9 moles of "D" and 14 moles of E are allowed to react in a closed vessel according to given reactions. Calculate number of moles of B formed in the end of reaction, if 4 moles of G are present in reaction vessel. (percentage yield of reaction is mentioned in the reaction) Step -1 3D+4E 80%rarr5C+A Step-2 3C+5G 50%rarr 6B+F

For the reaction A + 2B to C , 5 moles of A and 8 mole of B will produce

Hydrogen (a moles ) and iodine (b moles ) react to give 2x moles of the HI at equilibrium . The total number of moles at equilibrium is