Calculating Kp: In an equilibrium mixtur...

Calculating `K_p`: In an equilibrium mixture at `500^@C`, we find that `P_(NH_3)=0.076` atm, `P_(N_2)=3.00` atm, and `P_(H_2)=1.85` atm. Calculate `K_p` at `500^@C` for the following reaction
`N_2(g)+3H_2(g)hArr 2NH_3(g)`

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Equilibrium constant K_(C) for the following reaction at 800 K is, 4 NH_(3)(g)hArr (1)/(2)N_(2)(g)+(3)/(2)H_(2)(g) . The value of K_(p) for the following reaction will be N_(2)(g)+3H_(2)(g)hArr 2NH_(3)(g)

Calculating `K_p`: In an equilibrium mixture at `500^@C`, we find that `P_(NH_3)=0.076` atm, `P_(N_2)=3.00` atm, and `P_(H_2)=1.85` atm. Calculate `K_p` at `500^@C` for the following reaction `N_2(g)+3H_2(g)hArr 2NH_3(g)`

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Calculating `K_p`: In an equilibrium mixture at `500^@C`, we find that `P_(NH_3)=0.076` atm, `P_(N_2)=3.00` atm, and `P_(H_2)=1.85` atm. Calculate `K_p` at `500^@C` for the following reaction
`N_2(g)+3H_2(g)hArr 2NH_3(g)`