[" OBJECTIVE TYPE "],[" fA(g),B(g) and C(g) uno "],[" (g) "+C(g)],[" gas ig present then total "],[" a "=60M_(0)=40J]

For the reaction, A(g) rarr B(g) +C(g) Select the correct graph.

A sample of mixture of A(g), B (g) and C(g) under equilibrium has mean molecular mass equal to 80. The equilibrium is : A(g)hArr B(g)+C(g) If initially 4 mole of 'A' gas is present then total number of mole at equilibrium is : [M_(A)=100,M_(B)=60,M_(C)=40]

A sample of mixture of A(g), B (g) and C(g) under equilibrium has mean molecular mass equal to 80. The equilibrium is : A(g)hArr B(g)+C(g) If initially 4 mole of 'A' gas is present then total number of mole at equilibrium is : [M_(A)=100,M_(B)=60,M_(C)=40]

For 2A(g) B(g) +3C(g) , Pressure of A at t = 0 is 500 mm, then total pressure of A, B & C at t = 10 min is( in mm)

For the reaction A_((g)) hArr B_((g)) + C_((g))

For a first order gas phase reaction : A_((g)) to 2B_((g)) +C_((g)) P_(0) be initial pressure of A and P_(t) the total pressure at time 't'. Integrated rate equation is :

For a first order gas phase reaction : A_((g)) to 2B_((g)) +C_((g)) P_(0) be initial pressure of A and P_(t) the total pressure at time 't'. Integrated rate equation is :

A sample of mixture of A(g),B(g) and C(g) under equilibrium has a mean molecular weight (observed ) is 80. The equilibrium is underset((mol.wt.=100))(A(g))hArrunderset((mol.wt.=60))(B(g))+underset((mol.wt.=40))(C(g)) Find the degree of dissociation alpha for A(g)

For the reaction A(g) iff B (g), K_(C)=10 B(g) iff C(g), K_(C)=2 C(g) iff D(g), K_(C)=0.01 Calculate K_(C) for the reaction D(g) iff A(g) .

For the reaction A(g) iff B (g), K_(C)=10 B(g) iff C(g), K_(C)=2 C(g) iff D(g), K_(C)=0.01 Calculate K_(C) for the reaction D(g) iff A(g) .