For the reaction,
`A(g)+2B(g)rarrC(g)+D(g)" "((dx)/(dt))=k[A][B]^(2)`
Initial pressure of A and B are respectively `0.60` and `0.80` atm. At a time when pressure of C is `0.20` atm rate of the reaction, relative to the initial value is :

The reaction A(g)+2B(g)rarrC(g)+D(g) is an elementary process. In an experimetn, the initial partial pressure of A and B are P_(A)= 0.60 and P_(B)= 0.80 atm . When P_(C )=0.2 atm , the rate of reaction relative to the initial rate is

The reaction A(g) + 2B(g) rarr C(g) + D(g) is an elementary process. In an experiment involvig this reaction, the initial partial pressure of A and B are p_(A) = 0.60 atm and p_(B) = 0.80 atm , respectively. When p_(C ) = 0.20 atm , the rate of reaction relative to the initial rate is

The reaction A(g) + 2B(g) to C(g) is an elementary reaction. In an experiment involving this reaction, the initial pressures of A and B are ​ P_A = 0.40 atm and P_B = 1.0 atm respectively. When P_C =0.3 atm, the rate of the reaction relative to the initial rate is:-

In an elementary reaction A(g)+2B(g) to C(g) the initial pressure of A and B are P_(A)=0.40 atm and P_(B) =0.60 atm respectively. After time T, if pressure of C is observed 0.1 atm, then find the value of (r_(i) (" initial rate of reaction"))/(r_(t)(" rate of reaction after time t")) .

For the reaction A_(2)(g) + 2B_(2)hArr2C_(2)(g) the partial pressure of A_(2) and B_(2) at equilibrium are 0.80 atm and 0.40 atm respectively.The pressure of the system is 2.80 atm. The equilibrium constant K_(p) will be

For the reaction at 127^@ C N_2(g) + 3H_2(g) hArr 2NH_3(g) the partial pressures of N_2 and H_2 are 0.80 and 0.40 atm respectively at equilibrium. The total pressure of the system is 2.80 atm. Calculate K_p and K_c for the reaction.

For the reaction, N_(2)(g)+3H_(2)(g) hArr 2NH_(3)(g) the partial pressure of N_(2) and H_(2) are 0.80 and 0.40 atmosphere, respectively, at equilibrium. The total pressure of the system is 2.80 atm. What is K_(p) for the above reaction?