Question

Question #97b1f

Answer 1

`= 13.879 " g"`

[to the nearest hundredth of a gram]

Explanation:

You'll need the Pu-239 half life which Google tells me is: `24,100 " years"`

For exponential decay `A(t) = A_o e^(-kt)` we can say this about the half life, `tau`:

`A(tau) = A_o/2 = A_o e^(- k tau ) implies k = (ln 2)/tau`

`A(t) = A_o e^(- (ln 2)/tau t)`

`A(t = 75,000) = 120 cdot e^(- (ln 2)/(24,100) cdot 75,000)`

`= 13.879 " g"`

Reality check, that is almost 3 half lives so we should get in the order of: `120 * (1/2)^(color(red)(3)) = 15 " g"`

Answer 2

The mass is `=13.891g`

Explanation:

The half life of Plutonum 239 is `t_(1/2)=2.4*10^4 years`

The radioactive decay constant is `lambda=ln2/(t_(1/2))`

So,

`lambda=ln2/(2.4*10^4 )=0.69/(2.4*10^4 )`

`=0.2875*10^-4 (years^-1)`

We apply the equation

`A=A_0*e^(-lamdat)`

The activity is proportional to the mass.

`m=m_0*e^(-lamdat)`

`m=120*e^-(0.2875*10^-4*75000)`

`m=120*e^-2.15625`

`m=120*0.11576`

`m=13.891g`