In an acidic medium, the rate of reaction between `(BrO_(3)^(ɵ))` and `Br^(ɵ)` ions is given by the expresison
`(-d[BrO_(3)^(ɵ)])/(dt) = k[BrO_(3)^(ɵ)] [Br^(ɵ)] [H^(o+)]^(2)`
It means

In acidic medium, the rate of reaction between BrO_(3)^(ɵ) and Br^(ɵ) is given by the expression (-d[BrO_(3)^(ɵ)])/(dt) =k[BrO_(3)^(ɵ)][Br^(ɵ)][H^(o+)]^(2)

In acidic medium the rate of reaction between [BrO_(3)^(-)] and [Br^(-)] ions given by the expression - (d[BrO_(3)^(-)])/(dt) = k [BrO_(3)^(-)][Br^(-)][H^(+)]^(2) It means (i) rate of constant of the reaction depends upon the concentration of H^(+) ions (ii) rate of reaction is independent of the concentration of acid added (iii) the change in pH of the solution will affect the rate of reaction (iv) doubling the concentration of H^(+) ions will increase the reactions rate by 4 items.

How do you distinguish between Br^(ɵ) and NO_(3)^(ɵ) ions?

How many Faradays are required to reduce 1 mol of BrO_(3)^(-) to Br^(-) in basic medium ?

In the reaction 3Br_(2)+6CO_(3)^(2-)+3H_(2)Orarr5Br^(ө)+BrO_(3)^(ө)+6HCO_(3)^(ө)

The order of reaction is an experimentally determined quanity. It may be zero, poistive, negative, or fractional. The kinetic equation of nth order reaction is k xx t = (1)/((n-1))[(1)/((a-x)^(n-1)) - (1)/(a^(n-1))] …(i) Half life of nth order reaction depends on the initial concentration according to the following relation: t_(1//2) prop (1)/(a^(n-1)) ...(ii) The unit of the rate constant varies with the order but general relation for the unit of nth order reaction is Units of k = [(1)/(Conc)]^(n-1) xx "Time"^(-1) ...(iii) The differential rate law for nth order reaction may be given as: (dx)/(dt) = k[A]^(n) ...(iv) where A denotes the reactant. For a reaction: I^(ɵ) + OCl^(ɵ) rarr IO^(ɵ) + Cl^(ɵ) in an aqueous medium, the rate of the reaction is given by (d[IO^(ɵ)])/(dt) = k([I^(ɵ)][OCl^(ɵ)])/([overset(ɵ)(OH)]) The overall order of the reaction is

18 " mL of " 1.0 M Br_(2) solution undergoes complete disproportionation in basic medium to Br^(The hardness of water in terms of ) and BrO_(3)^(ɵ) . Then the resulting solution required 45 " mL of " As^(3+) solution to reduce BrO_(3)^(ɵ) to Br^(ɵ) . As^(3+) is oxidised to As^(5+) which statements are correct?

What is geometry of ClO_2^(ɵ),ClO_3^(ɵ) and ClO_4^(ɵ) ions?

For the reaction 5Br^(-)(aq)+BrO_(3)^(-)(aq)+6H^(+)(aq)rarr 3Br_(2)(aq)+3H_(2)O(l) the reate expression was found to be -(d[BrO^(3-)])/(dt)=k[Br^(-)][H^(+)]^(2)[BrO_(3)^(-)] Which of the following statements is /are correct? I. Doubling the intial concentration of all the reactants will increase the reaction rate by a factor of 8. II. Unit of rate constant of the reaction in a buffer solution is "min"^(-1) III. Doubling the concentration of all the reactants at the same time will increase the reaction rate by a factor of 16 IV. rate of conversion of BrO_(3)^(-) and rate of disappearance of Br^(-) are the same

In the following reaction, how is the rate of appearance of the underlined Product related to the rate of disappearance of the underlined reactant ? BrO_(3)^(ɵ)(aq) + 5underline(Br)^(ɵ)(aq) + 6H^(o+) (aq) rarr 3underline(Br_(2))(l) + 3H_(2)O(l)