Equal number of moles of $$A$$ and $$B$$ are allowed to react with each till it reaches equilibrium $$2A+B\rightleftharpoons C+D$$ The value of $$K_{c}$$ for this equilibrium can never be
A
$$<1$$
B
$$\infty$$
C
$$>1$$
D
$$=1$$
Open in App
Solution
Verified by Toppr
Correct option is D. $$\infty$$
Was this answer helpful?
0
Similar Questions
Q1
Equal number of moles of $$A$$ and $$B$$ are allowed to react with each till it reaches equilibrium $$2A+B\rightleftharpoons C+D$$ The value of $$K_{c}$$ for this equilibrium can never be
View Solution
Q2
52.2A+B=C+2D, 4 moles of A are mixed with 2 moles of B and the mixture is kept in one litre flask till the equilibrium is reached. At equilibrium 2 moles of D are formed. Calculate the value of kc
View Solution
Q3
3 moles of A and 4 moles of B are mixed together and allowed to come into equilibrium according to the following reaction:
A(g)+4B(g)⇌2C(g)+3D(g)
When equilibrium is reached, there is 1 mole of C. The equilibrium constant of the reaction is:
View Solution
Q4
Calculate $$K_c$$ for the reaction: $$A(g)+B(g)\rightleftharpoons 2C(g)$$, if $$1$$ mole of A, $$1.4$$ moles of B and $$0.50$$ mole of C are placed in a one-litre vessel and allowed to reach equilibrium. The equilibrium concentration of C is $$0.75$$ mole per litre.
View Solution
Q5
The following reaction was allowed to come to equilibrium A(g)+2B(g)⇌C(g). The initial amounts of reactants placed into a 5 lt. vessel were 1 mole of A and 1.8 mole of B. After the reaction reached equilibrium. 1 mole of B was found. Calculate the value of kc for this reaction.