`AtoB` first order reaction A is ooptical active and B is optically inactive. A series of experiment were conducted on a solution of A
`{:(,"Time",0,60 min,oo),(,"optical rotation",82^(@),77^(@),2^(@)):}`
assume some imurity is present calculate the otical rotation for 5 hours.)
(Given in 1.066=0.064, `e^(0.16)`=1.17)

A first order reaction takes 40 min for 30% decomposition. Calculate t_(1//2) . (Given log 7 =0.845)

The rate of first-order reaction is 1.5 xx 10^(-2) M "min"^(-1) at 0.5 M concentration of reactant. The half-life of reaction is

The rate of first order reaction is 1.5 xx 10^(-2) mol L^(-1) min ^(-1) at 0.5 M concentration of the reactant. The half-life of the reaction is

The hydrolysis of sucrose was studied with the help of calorimeter and following data were {:(,"Collected time (min.)",:0,70,oo),(,"observed rotation (degrees)",:44,16.5,-11):} the time taken when reaction mixture wil be optically inactive ? (Given : In 2=0.7,in 3=1.1, in 5=1.6)

For a first order reaction A to B the reaction rate at reactant concentration of 0.01 M is found to be 2.0 xx 10 ^-5mol L^(-1) s^(-1) . The half-life period of the reaction is

Arsine decomposes on heating according to the equation 2AsH_(3)(g) rarr 2As(s) + 3H_(2)(g) . The decompoistion was studied at constant temperature and constant volume by measuring the total pressure at various intervals of time. |{:("Time (min)",0,5,7.5,10),("Total Pressure (atm)",1,1.09,1.13,1.16):}| Assume it to be a first order reaction, calculate the specific rate constant and half life of the reaction.

For a first-order reaction A rarr B the reaction rate at reactant concentration of 0.01 M is found to be 2.0 xx 10^(-5) "mol" L^(-1) s^(-1) . The half-life period of the reaction is

For a first-order reaction A rarr B the reaction rate at reactant concentration of 0.10 M is found to be 2.0 xx 10^(-5) "mol" L^(-1) s^(-1) . The half-life period of the reaction is