Question #bb66f

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Question #bb66f

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Answer 1 · 2016-06-15T13:27:17

Here's what I got.

Explanation:

A radioactive nuclide's nuclear half-life is defined as the time needed for half of an initial sample to undergo radioactive decay.

My own work

If you take $N_{0}$ $"N"_0$ to be the initial concentration of your radioactive nuclide $X$ $"X"$ , you can say that you will be left with

$\frac{1}{2} \cdot N_{0} = \frac{N_{0}}{2} \to$ $1/2 * "N"_0 = "N"_0/2 ->$ after the passing of one half-life

$\frac{1}{2} \cdot \frac{N_{0}}{2} = \frac{N_{0}}{4} \to$ $1/2 * "N"_0/2 = "N"_0/4 ->$ after the passing of two half-lives

$\frac{1}{2} \cdot \frac{N_{0}}{4} = \frac{N_{0}}{8} \to$ $1/2 * "N"_0/4 = "N"_0/8 ->$ after the passing of three half-lives
$⋮$ $vdots$

and so on.

This means that you can express the amount of the nuclide that remains undecayed after a period of time $t$ $t$ like this

$color(blue)(|bar(ul(color(white)(a/a)"N"_t = "N"_0 * 1/2^ncolor(white)(a/a)|)))" " " "color(orange)("(*)")$

Here

$n$ - the number of half-lives that pass in the given period of time $t$

All you have to do now is pick a period of time $t$ and use the known ratio that exists between $"N"_t$ and $"N"_0$ to find $n$ .

For example, for $t=0 -> t="5 h"$ you have

$"N"_t/"N"_0 = 1/2^n = 0.6484$

This is equivalent to

$2^n = 1/0.6484$

$ln(2^n) = ln(1/0.6484)$

$n * ln(2) = ln(1/0.6484) implies n = ln(1/0.6484)/ln(2) = 0.625$

So, you know that $0.625$ half-lives pass in $5$ hours, which means that the half-life of the nuclide, $t_"1/2"$ , is

$t_"1/2" = "5 h"/0.625 = color(green)(|bar(ul(color(white)(a/a)color(black)("8 h")color(white)(a/a)|)))$

I recommend using different time periods to find $n$ , the half-life must come out the same in every case. That is the case because radioactive decay is a first-order reaction, meaning that its half-life is constant throughout the decay process.

For example, for $t=0 -> t = "18 h"$ you have

$"N"_t/"N"_0 = 0.2102$

This time you get

$n = ln(1/0.2102)/ln(2) = 2.25$

Once again, you have

$t_"1/2" = "18 h"/2.25 = "8 h"$

For the second part, use the half-life of the reaction to find the value of $n$

$n = (64 color(red)(cancel(color(black)("h"))))/(8color(red)(cancel(color(black)("h")))) = 8$

then use equation $color(orange)("(*)")$ to find the mass of the nuclide that remains undecayed

$"N"_t = "2.500 mg" * 1/2^8$

$"N"_t = "0.009766 mg"$

This means that the amount of the nuclide that decayed is

$"N"_"decayed" = "2.500 mg" - "0.009766 mg" = color(green)(|bar(ul(color(white)(a/a)color(black)("2.490 mg")color(white)(a/a)|)))$

I'll leave the answer rounded to four sig figs.

Answer 2 · 2016-10-20T13:49:34

The half life is 8 hours.

Explanation:

O.K., this is actually one that requires almost no math to solve!

As you know, or are learning, a half-life is the amount of time it takes for half of a radioactive element to decay. So, in the language of your question Nt/N0 = 0.5 at one half life.

Looking at your chart, we see that that happened somewhere between 5 and 10 hours.

Now we also know that after two half lives Nt/N0 will be 0.25.

Woa!!!! THAT's ON THE CHART!!!! Awesome!

Two half-lives = 16 hours.. Therefore one half-life = 8 hours.

Wait! Does that check with the previous observation that the half-life will be between 5 and 10 hours? Yup! O.K.! We are in business!

On to part B! 64 hours is 64/8 half-lives = 8 half-lives. After 8 half-lives there will be $1/2^8$ of the original substance remaining. or 0.00390625 * original mass remaining. So we have lost (2.500 - (0.00390625*2.500)) grams, or 2.4902 grams of the original material.

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