Using the half – lives of radioactive elements. In this presentation we will learn: 1.That there is an isotope of carbon that is useful for dating materials.

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Presentation transcript:

Using the half – lives of radioactive elements

In this presentation we will learn: 1.That there is an isotope of carbon that is useful for dating materials that have once been alive many years ago. 2.That there is a useful relationship between the radioactive decay constant and half- life that we can call upon to work out the age of ancient artifacts. 3.That we can call upon Avogadro’s number to quickly calculate the number of atoms in any given mass of a sample of known atomic mass.

You’ve probably heard of radiocarbon dating. This is how it works. The CO 2 that plants take in is slightly radioactive. This is due to some radioactive Carbon formed in the atmosphere by cosmic rays. 12 C is turned, magically, into a radioisotope 14 C. When alive, plants have a constant ratio of these isotopes in their tissue. So do you – you’re breathing! When they die, 14 C is no longer replenished. It starts to decay. The nuclei obey our model rule – a constant probability of a decay in a fixed time. And what’s the time scale? In this case, few thousand years.

Atoms of 14 C Time in thousands of years 14 C when alive 14 C after death: decay by half every 5570 years y

In the next 5570 years, HALF of what there is of the 14 C will decay. In the following 5570 years, half of what’s left decays (leaving ¼) and so on. This is the HALF – LIFE of 14 C. Half – life is NOT half the total life. It’s the time taken for half of what there is to decay. A half-life of thousands, or billions, of years can be found in a few minutes! 1.Find the activity of the sample of a KNOWN number of radioactive nuclei. 2.From this find the decay constant. activity = N.

3. Use this simple formula: = t 1/2 Half - life ln 2 = Half – life tells you how long the substance lasts. The decay constant tells you how fast it decays. Another RECIPROCAL relationship!

Radioactive clock: In L half – lives, number of nuclei N is reduced by a factor 2 L. e.g. in 3 half-lives, N is reduced by 2 3 = 8. Find activity. Find factor F by which activity has been reduced. Calculate L so that 2 L = F L =log 2 F Age = t ½ L

Example The carbon in an axe handle was found to contain 1 part in Carbon14. How old is the axe? Originally, the C14 was one part in After one half-life, it’s down to one part in After 2 half-lives, the C14 is down to one part in So, the age of the axe must be…………………………. ……………….2 x 5600 years = years old.

Finding ages of rocks Uranium isotopes have long half-lives and decay into LEAD, which is stable. e.g. U 238 half-life = 4.5 billion years. Initially the rock contains 100% U, 0% Pb. After one half-life, it’s 50% U, 50% Pb. After 2 half-lives, it’s 25% U, 75% Pb. After 3 half-lives, it’s 12.5% U, 87.5% Pb……and so on.. (you don’t usually go more than 3 half-lives).

RATIO of U to Pb: Initially: 1:0 U to Pb After one half-life: 1:1 After 2 half-lives: 1:3 After 3 half-lives: 1:7 LEARN THESE RATIOS!!!

The same thing applies to Potassium 40. It decays into Argon 40, which is stable. It’s used to date IGNEOUS rocks The same ratios apply: Initially1:0 40 K: 40 Ar After one half-life1:1 After 2 half-lives1:3 After 3 half-lives1:7

Some typical AS and A2 examples of radioactivity:

Examples: Q1. 90 Sr has a half-life of 27 years. 24 Na has a half-life of 15 hours. a)Which is more active? Why? b)After how long will their activities be equal? Q Pu has a half-life of year and an activity of 1.5 x Bq. Each alpha particle has an energy of 5 Mev. (1 year = 3 x 107 s). a)What’s the power output of 239 Pu? b)What’s its approximate power output after years? c)How much energy does it emit in one year? What assumption have you made?

Answers: 1 a) 24 Na, because in one second more Na atoms will disintegrate than Sr atoms. 1 b) 27 years is 1.6 x 10 4 longer than 15 hours. Initially, Na will be 1.6 x 10 4 times more active than Sr. After n periods of 15 hours it will have fallen by a factor of 1.6 x 10 4 Where 2 n = 1.6 x 10 4 n is approximately x 15 hours = 9 days.

Answers, continued: 2 a) Power = 5 x 10 6 x 1.6 x x 1.5 x Js -1 = 12 W 2 b) Power is approximately ½, since this is after 1 half-life. 2 c) Power over 1 year = 3 x 10 7 x 12 = 3.6 x 10 8 W, assuming power is constant over one year.

Q3. A sample of radioactive material contains atoms. Its half-life is 2 days. a)What is the fraction of atoms remaining after 5 days? b)What is the activity of the sample after 5 days? Q4. 87 Kr has a half-life of 78 minutes. What is the activity of 10  g of 87 Kr? (L = 6.0 x mol -1 ) Q5. A radioactive material has an activity of 9.0 x Bq. Its half-life is 80.0 s. How long will it take for its activity to reach 2.0 x Bq?

Answers: 3 a) N/No = e - t = ln2/half-life=0.693/2.0 days -1 t = x 5.0/2.0=1.73 So N/N o = e –1.73 = b) dN/dt = - N N = x = 0.693/2 x 24 x 3600 s -1 So dN/dt = - (0.693 x x )/2 x 24 x 3600 = x s -1.

Answers:  g of 87 K contains 10 x x 6 x /87 atoms = 6.9 x atoms dN/dt = - N = 0.693/ 78 x 60 s -1 So dN/dt = x 6.9 x / 78 x 60 = 1.02 x Bq 5. N/No = e - t, so A/A o = e - t since N is proportional to A. So ln (A/A o ) = - t And therefore ln (2 x )/(9 x ) = x t/80 t = 174 s

Radioactive dating questions. Q C has a half-life of 5570 years. It’s present as CO 2 in the atmosphere. The rate of production of 14 C and therefore its concentration, has stayed fairly constant over the past years. All living organisms contain a small amount of 14 C when they are alive. When they die, they stop exchanging CO 2 with the atmosphere. a)When an organism is alive, it contains 1 atom of 14 C to every atoms of 12 C. In one second, a fraction 4 x of the atoms of 14 C may decay. Estimate the activity of one gram of 14 C from a living organism. ( L = 6.0 x mol -1 ) b)What activity would you expect from the bones of a bison eaten by man years ago, during the Ice Age? c)It is found that the ratio of 14 C to 12 C in a piece of wood is 0.2 x , whereas that in living wood is 0.8 x When did the wood die?

Q2. A rock contains radioactive Potassium, 40 K, which decays to a stable isotope of Argon, 40 Ar. The decay rate in the sample is 0.16 Bq. Mass of Potassium in the sample is 0.6 x g Mass of Argon in the sample is 4.2 x g a)Find for the Potassium and its half-life. b)Find the age of the rock, assuming there was no Argon in the rock originally. c)Write about difficulties involved in measuring an activity of 0.16 Bq.

Answers to radioactive dating questions: Q1 a) 1 g of 12 C contains 0.5 x atoms. So 1 g C contains 0.5 x atoms of 14 C. Fraction of atoms decaying per s = 4 x So number of 14 C atoms decaying per s = 0.5 x x 4 x = 20 Bq b) y is approx 2 half-lives. Activity is approx 5 Bq. c) 14 C/ 12 C(old) = 0.2 x C/ 12 C(new) = 0.8 x So the factor relating to the time taken to decay is 0.8/0.2 = 4. This amounts to a factor of 2 2 or 2 half-lives. The age of the wood is years.

Q2 a) dN/dt = - N So 0.16 = - x 0.6 x x 6 x /40 = - x 0.09 x Thus = 1.8 x s -1. And the half-life is 0.693/ = 1.3 x 10 9 years. b) Total 40 K originally is 0.6 x g, or 1/8 of the original. Since 1/8 is 1/2 3, the rock is 3 half-lives old, or about 4 x 10 9 years old. c) The background count could be bigger than 0.16 Bq, leading to measurement problems.