A drop of solution (volume `0.05 mL`) contains `3 xx 10^(-6) "mole" H^(o+)` ions. If the rate constant of disappearance of `H^(o+)` ions is `1 xx 10^(7) mol L^(-1) s^(-1)`, how long would it take for `H^(o+)` ions in the drop of disappear?

A drop of solution (volume 0.10 ml) contains 6 xx 10^(–6)" mole of "H^(+) , if the rate constant of disappearance of H^(+) is 1 xx 10^(7)" mole litre"^(–1)" sec"^(–1) . How long would it take for H^(+) in drop to disappear ?

A drop of solution ("volume" =0.05 mL) contains 3xx10^(-2) mole of H^(+) . If the rate constant of disappearance of H^(+) is 1.0xx10^(2) mol litre^(-1) minute^(-1) . How long (in minutes) will it take to disappear all the H^(+) ions?

A drop of a solution (0.05 mL) contains 6.0xx10^(-7) mole of H^(+) . If the rate of disappearance of H^(+) is 6.0xx10^(5) mol litre^(-1) sec^(-1) , it takes x xx10^(-8) sec for H^(+) in the drop to disappear. Find the value of x .

For the reaction 4NH_(3) + 5O_(2) to 4NO + 6H_(2) O , if the rate of disappearance of NH_(3) is 3.6 xx 10^(-3) mol L^(-1) s^(-1) , what is the rate of formation of H_(2) O

For the reaction H_(2) (g)+I_(2)(g) rarr 2HI(g) , the rate of disappearance of HI will be 1.0 xx 10^(-4) mol L^(-1) s^(-1) . The rate of appearance of HI will be

The rate constant of the first order, decomposition of N_(2)O_(5) at 25^(@) is 3.00 xx 10^(-3) min^(-1) . If the initial concentration of N_(2)O_(2) is 2.00 xx 10^(-3) mol L^(-1) , How long will it take for the concentration to drop to 5.00 xx 10^(-4) mol L^(-1) ?