Given that for a reaction of nth order, ...

Given that for a reaction of nth order, the integrated rate equation is:
`K=1/(t(n-1))[1/C^(n-1)-1/C_(0)^(n-1)]`, where `C` and `C_(0)` are the concentration of reactant at time `t` and initially respectively. The `t_(3//4)` and `t_(1//2)` are related as `t_(3//4)` is time required for C to become `C_(1//4`) :

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Given that for a reaction of nth order the integrated rate equation is K=1/(t(n-1))[1/(C^(n-1))-1/(C_(0)^(n-1))] where C and C_(0) are the concentration of reactant at time to initiallyh respectivley. The t_(3//4) and t_(1//2) are related as ( t_(3//4) is time required to C to become C/4)

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