For the reaction h,(g) + 1,(g) 2hi(g) at 721k the value of equilibrium constant (k) is 50. When the equilibrium concentration of both is 0.5m, the value of k under the same conditions will be
Answers
Answer:
The value of k under the same conditions will be 50.0.
Explanation:
The equilibrium reaction is H
The equilibrium reaction is H 2
The equilibrium reaction is H 2
The equilibrium reaction is H 2 (g)+I
The equilibrium reaction is H 2 (g)+I 2
The equilibrium reaction is H 2 (g)+I 2
The equilibrium reaction is H 2 (g)+I 2 (g)⇔2HI(g).
The equilibrium reaction is H 2 (g)+I 2 (g)⇔2HI(g).The relationship between K
The equilibrium reaction is H 2 (g)+I 2 (g)⇔2HI(g).The relationship between K p
The equilibrium reaction is H 2 (g)+I 2 (g)⇔2HI(g).The relationship between K p
The equilibrium reaction is H 2 (g)+I 2 (g)⇔2HI(g).The relationship between K p and K
The equilibrium reaction is H 2 (g)+I 2 (g)⇔2HI(g).The relationship between K p and K c
The equilibrium reaction is H 2 (g)+I 2 (g)⇔2HI(g).The relationship between K p and K c
The equilibrium reaction is H 2 (g)+I 2 (g)⇔2HI(g).The relationship between K p and K c is K
The equilibrium reaction is H 2 (g)+I 2 (g)⇔2HI(g).The relationship between K p and K c is K p
The equilibrium reaction is H 2 (g)+I 2 (g)⇔2HI(g).The relationship between K p and K c is K p
The equilibrium reaction is H 2 (g)+I 2 (g)⇔2HI(g).The relationship between K p and K c is K p =K
The equilibrium reaction is H 2 (g)+I 2 (g)⇔2HI(g).The relationship between K p and K c is K p =K c
The equilibrium reaction is H 2 (g)+I 2 (g)⇔2HI(g).The relationship between K p and K c is K p =K c
The equilibrium reaction is H 2 (g)+I 2 (g)⇔2HI(g).The relationship between K p and K c is K p =K c (RT)
The equilibrium reaction is H 2 (g)+I 2 (g)⇔2HI(g).The relationship between K p and K c is K p =K c (RT) Δn
The equilibrium reaction is H 2 (g)+I 2 (g)⇔2HI(g).The relationship between K p and K c is K p =K c (RT) Δn .
The equilibrium reaction is H 2 (g)+I 2 (g)⇔2HI(g).The relationship between K p and K c is K p =K c (RT) Δn .For the equilibrium reaction, Δn=2−(1+1)=0.
The equilibrium reaction is H 2 (g)+I 2 (g)⇔2HI(g).The relationship between K p and K c is K p =K c (RT) Δn .For the equilibrium reaction, Δn=2−(1+1)=0.Hence, K
The equilibrium reaction is H 2 (g)+I 2 (g)⇔2HI(g).The relationship between K p and K c is K p =K c (RT) Δn .For the equilibrium reaction, Δn=2−(1+1)=0.Hence, K p
The equilibrium reaction is H 2 (g)+I 2 (g)⇔2HI(g).The relationship between K p and K c is K p =K c (RT) Δn .For the equilibrium reaction, Δn=2−(1+1)=0.Hence, K p
The equilibrium reaction is H 2 (g)+I 2 (g)⇔2HI(g).The relationship between K p and K c is K p =K c (RT) Δn .For the equilibrium reaction, Δn=2−(1+1)=0.Hence, K p =K
The equilibrium reaction is H 2 (g)+I 2 (g)⇔2HI(g).The relationship between K p and K c is K p =K c (RT) Δn .For the equilibrium reaction, Δn=2−(1+1)=0.Hence, K p =K c
The equilibrium reaction is H 2 (g)+I 2 (g)⇔2HI(g).The relationship between K p and K c is K p =K c (RT) Δn .For the equilibrium reaction, Δn=2−(1+1)=0.Hence, K p =K c
The equilibrium reaction is H 2 (g)+I 2 (g)⇔2HI(g).The relationship between K p and K c is K p =K c (RT) Δn .For the equilibrium reaction, Δn=2−(1+1)=0.Hence, K p =K c =50.