Following data are obtained for the reaction :
`N_(2)O_(5)rarr2NO_(2)+(1)/(2)O_(2)`
`{:(t(s)," "0," "300," "600),([N_(2)O_(5)("mol.L"^(-1))],1.6xx10^(-2),0.8xx10^(-2),0.4xx10^(-2)):}`
Calculate the half-life.

Following data are obtained for the reaction : N_(2)O_(5)rarr2NO_(2)+(1)/(2)O_(2) {:(t(s)," "0," "300," "600),([N_(2)O_(5)("mol.L"^(-1))],1.6xx10^(-2),0.8xx10^(-2),0.4xx10^(-2)):} Show that it follows first order reaction.

Discuss the rate of the reaction 2N_(2)O_(5(g)) rarr 4NO_(2(g))+O_(2(g))

Write the rate law of 2N_(2)O_(5(g))rarr 4NO_(2(g))+O_(2(g)) reaction.

For the reaction ,2S_(2)O_(4)^(2-)+1_(2)toS_(4)O_(6)^(2-)+2I^(-) -

The initial concentration of N_(2)O_(5) in the following first order reaction N_(2)O_(5)rarr2NO_(2)(g)+(1)/(2)O_(2)(g) " was "1.24xx10^(-2)"mol.L"^(-1) at 318K. The concentration of N_(2)O_(5) after 60minutes was 0.20xx10^(-2)"mol.L"^(-1) . Calculate the rate constant of the reaction at 318K.

The following data were obtained during the first order thermal decomposition of N_(2)O_(5)(g) at constant volume: 2N_(2)O_(5)(g)rarr4NO_(2)(g)+O_(2)(g) {:("SI.No","Time(s)","Pressure (atm)"),(1.,0,0.5),(2.,100,0.512):} Calculate the rate constant.

For the reaction 2N_(2)O_(5)(g)rarr4NO_(2)(g)+O_(2)(g) the rate of formation of NO_(2)(g)" is "2.8xx10^(3)(M).s^(-1) . Calculate the rate of disappearance of N_(2)O_(5)(g) .

For the reaction , N_(2)(g)+3H_(2)(g)rarr2NH_(3)(g),(1)/(2)(d[NH_(3)])/(dt) = 2xx10^(-4)"mol.L"^(-1).s^(-1) Find rate of disappearance of N_(2) & H_(2)

The following concentrations were obtained for the formation of NH_3 from N_2 and H_2 at equilibrium at 500K. [N_2] = 1.5 xx 10^-2M. [H_2] = 3.0 xx10^-2 M and [NH_3] =1.2 xx 10^-2 M . Calculate equilibrium constant.

((0.000008)^(-2/3)xx(0.0081)^(3/4)xx10^(-2))/((0.0256)^(-1/2)xx(0.125)^(1/3)xx(0.3)^(2))