2

4

6

8

16

Since the rate law can be expressed as rate=k[A₂]², tripling the concentration of A₂ will cause a 9-fold increase in the rate of the reaction

Since the rate law can be expressed as rate=k[A₂][B], doubling the concentrations of A₂ and B will quadruple the rate of the reaction.

Since the rate law can be expressed as rate=k[A₂]²[B], tripling the concentration of A₂ while keeping the concentration of B constant will triple the rate of the reaction

Since the rate law can be expressed as rate=k[A₂][B]², doubling the concentration of B while keeping the concentration of A₂ constant will double the rate of the reaction

Rate = k[NO]², because the initail rate quadrupled when [NO] was doubled but remained constant when [Cl₂] was doubled.

Rate = k[NO][Cl₂], because the initial rate doubled when either [NO] or [Cl₂] was doubled

Rate = k[NO][Cl₂]², because the initial rate doubled when [NO] was doubled and quadrupled when [Cl₂] was doubled

Rate = k[NO]²[Cl₂], because the initial rate quadrupled when [NO] was doubled and doubled when [Cl₂] was doubled

2

3

4

6

8

The rate of reaction will remain the same, because k will decrease by half

The rate of reaction will double, because the rate is directly proportional to [S₂O₈^2-]

The rate of reaction will increase by a factor of four, because two moles of SO₄^2- are produced for each mole of S₂O₈^2- consumed

The rate of reaction will increase by a factor of four, because the reaction is second order overall