The rate law for the reaction `2N_2 O_5 to 4NO_2 + O_2` is

The half life for the reaction 2N_2O_5 to 4NO_2 + O_2 in 24 hrs at 30^@C . Starting with 10 g of N_2O_5 how many grams of N_2O_5 will remain after a period of 96 hours?

At 193^(@)C , the rate law for the reaction 2Cl_(2)O to 2Cl_(2) + O_(2) is rate = k[Cl_(2)O]^(2) . (a) How the rate changes if [Cl_(2)O] is raised to threefold of the original ? (b) How should [Cl_(2)O] be changed in order to order to double the rate ?

The rate of the reaction 2N_(2)O_(5) to 4NO_(2) + O_(2) can be written in three ways: (-d[N_(2)O_(5)])/(dt)=k[N_(2)O_(5)] (d[NO_(2)])/(dt)=k'[N_(2)O_(5)] (d[O_(2)])/(dt)=k''[N_(2)O_(5)] The relationship between k and k′ and between k and k′′ are-

The rate law for the reaction O_(3) + O rarr 2O_(2) is rate = k[O_(3)][NO] . Then which is/are correct? (more than one correct)

The rate law for the decomposition of N_2 O_5 is: rate = [N_2 O_5] . What is the significance of k in this equation?

The rate constant for the reaction, 2N_(2)O_(5) rarr 4NO_(2) + O_(2) is 3.0 xx 10^(-5) s^(-1) . If the rate is 2.40 xx 10^(-5) mol L^(-1) s^(-1) , then the initial concentration of N_(2)O_(5) (in mol L^(-1) ) is