The rate law for reaction `A +2B hArr C + 2D` will be :

The rate law for a reaction A + B to C + D is given by the expression k[A]. The rate of reaction will be

The rate law for elecentary reaction A+2B to C +2D will be _.

Rate law for the reaction A + 2B to C is found to be

The experimental rate law for a reaction 2A + 2B rarr Product, is V prop C_(A) C_(B)^(1//2) . If the concentration of both A and B are doubled the rate of reaction increases by a factor of

The gaseous reaction A + B hArr2C + D, + Q is most favoured at

The rate and mechamical reaction are studied in chemical kinetics. The elementary reactions are single step reaction having no mechanism. The order of reaction and molecularity are same for elementary reactions. The rate of forward reaction aA + bBrarr cC+dD is given as: rate =((dx)/(dt))=-1/a(d[A])/(dt)=-1/b(d[B])/(dt)=1/c(d[C])/(dt)=1/d(d[D])/(dt) or expression can be written as : rate =K_(1)[A]^(a)[B]^(b)-K_(2)[C]^(c )[D]^(d) . At equilibrium, rate = 0 . The constants K, K_(1), K_(2) are rate constants of respective reaction. In case of reactions governed by two or more steps reaction mechanism, the rate is given by the slowest step of mechanism. For a hypothetical reaction aA+bBrarr Product, the rate law is: rate =K[A]^(x)[B]^(y) , then:

The rate and mechamical reaction are studied in chemical kinetics. The elementary reactions are single step reaction having no mechanism. The order of reaction and molecularity are same for elementary reactions. The rate of forward reaction aA + bBrarr cC+dD is given as: rate =((dx)/(dt))=-1/a(d[A])/(dt)=-1/b(d[B])/(dt)=1/c(d[C])/(dt)=1/d(d[D])/(dt) or expression can be written as : rate =K_(1)[A]^(a)[B]^(b)-K_(2)[C]^(c )[D]^(d) . At equilibrium, rate = 0 . The constants K, K_(1), K_(2) are rate constants of respective reaction. In case of reactions governed by two or more steps reaction mechanism, the rate is given by the slowest step of mechanism. The rate of formation of SO_(3) in the following reaction, 2SO_(2)+O_(2)rarr 2SO_(3) is 10 g sec^(-1) The rate of disappearance of O_(2) will be: