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The Muon HalfLife Project

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... Half-Life Project ... Those that 'survived after 2 tosses' are those that you tossed 3 ... Go and download a unique set of data. Copy your data into the spreadsheet ... – PowerPoint PPT presentation

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Title: The Muon HalfLife Project


1
The Muon Half-Life Project
2
Intro
  • In this course, you will learn about radioactive
    decay, what a half-life is, and how to use
    analysis tools associated with these concepts,
    including graphs and formulas related to decay.
    Then, you will use these tools to determine the
    half-life of a particle known as the muon

3
Radioactive decay
  • First, what is radioactive decay?
  • Radioactive decay is the process by which an
    unstable subatomic particle emits other subatomic
    particles and energy.
  • Radioactive materials have an important property
    called a half-life, which is useful in various
    applications, such as dating.

4
Half-Life
  • The term half-life refers to the time it takes
    for half of the amount of a radioactive substance
    to decay.

5
Radioactive Substances
  • Some well known radioactive substances are
  • Uranium-238, Radium-226, Carbon-14
  • Uranium-238 has a half-life of about 4.5109
    years
  • The half-life of radium-226 is about 1600 years

6
Radioactive Particles
  • There are also radioactive particles such as free
    neutrons, pions, or muons.
  • A free neutron has a half life of about 11
    minutes and decays into a proton, an electron,
    and an electron antineutrino
  • Other neutrons do not decay because they are
    contained within stable nuclei.

7
Carbon-14
  • The half-life of carbon-14 is about 5730 years.
  • Because all living things contain some carbon-14,
    it is very useful for dating objects made of
    organic compounds, such as ancient campfires, or
    ancient human remains.

8
Carbon-14 (cont.)
  • You may be thinking, Well, if carbon-14 is
    radioactive and decays, why haven't we run out?
  • The reason we haven't run out is that carbon-14
    is continuously being produced in the atmosphere,
    and here's the cool thing, cosmic rays are
    responsible for this production.

9
Carbon-14 (cont.)
  • The production of carbon-14 is a two step process
  • First, a cosmic ray collides with an atomic
    nucleus in the air, this produces neutrons and
    other junk
  • The neutrons can then collide with Nitrogen-14 to
    produce carbon-14 and other junk
  • The junk is quite interesting, but it is not
    involved with the story of carbon-14

10
Carbon-14 (cont.)
  • Carbon-14 dating works by measuring the amount of
    carbon-14 left in a sample and comparing it with
    the amount of carbon-14 the sample would contain
    when it was new.
  • Example If you found an object that only had
    one quarter of its original carbon-14, it would
    be two half-lives, or 11460 years old.

11
Carbon-14 (cont.)
  • While organisms are alive (trees, humans,
    animals), they are taking in carbon-14 at the
    same rate as it is decaying. When the organisms
    die, the carbon-14 is no longer being replaced.
    Therefore, carbon dating is actually measuring
    the amount of time since an organism has died.

12
Carbon-14 (cont.)
  • Carbon-14 exhibits radioactive beta decay
  • C-14 --gt N-14 electron electron antineutrino
  • Because the atomic mass number stays the same,
    this means a neutron in carbon-14 is becoming a
    proton in nitrogen-14

13
Beaninium Archeology
  • In this activity, you will be dating samples of
    radioactive beaninium
  • When a sample of beaninium is new, the red/white
    ratio is 1/1
  • Beaninium has a half-life of 100 years
  • One final note, when the white decay, they
    disappear. They do not turn into red. (i.e. the
    number of red is the count of the original amount
    of white)

14
Samples
15
Table
  • Now, make a table that looks like this to keep
    your data about the samples

16
Answers
17
Twizzler Decay
  • In this next activity, you will be responsible
    for the decay of a twizzler
  • First, you will create a graph of the twizzler
    length vs half lives
  • Mark the original length, then eat half. A
    half-life has now passed. Mark the length again
    and continue until the twizzler is gone.

18
Twizzler Decay (cont.)
  • The graph should look something like this

19
Twizzler Decay (cont.)
  • You will then find a formula for the length of
    twizzler after n half-lives

20
Twizzler Decay (cont.)
  • The equation should look something like this
  • Where Ln is the current length and L0 is the
    original length

21
Estimate of Age
  • If you estimated the ages of G and H as 150 and
    75 years, we need to revise that estimate.
  • These ages would be correct if the decay were
    completely linear, but we just found that the
    decay is a curve

22
Estimate of Age (cont.)
  • By comparing the curve and the linear fit, how
    should the age estimate for G and H be changed?
    Higher? or Lower?

23
Decay Equation
  • Now find an equation for the length of the
    twizzler at any time, not just for integer
    half-lives
  • Hint How would you make an amount of time given
    the number of half-lives and the length of one
    half-life

24
Decay Equation (cont.)
  • Answer to Hint tnt1/2
  • We then use this to find
  • And the final equation should look like this

25
Logs
  • Properties of Logarithms
  • log(ab)log(a)log(b)
  • log(a/b)log(a)-log(b)
  • log(an)nlog(a)

26
Log Equation
  • Now use the tools you have acquired to find the
    ages of samples G and H from the bean archeology
    activity
  • Note This is the equation of a line ymxb

27
Answers
  • The age of sample G should be around 141 years
  • The age of sample H should be around 68 years

28
Whats a Muon?
  • A muon is a heavy electron about 207 x mass of
    electron
  • Discovered at Caltech in 1936 by Carl Anderson
    while studying cosmic rays
  • The muon is radioactive and decays into an
    electron and two neutral particles called
    neutrinos
  • This however, does not mean a muon is made of
    these things. It is a fundamental particle.

29
The Muon Half-Life
  • Because Muons are radioactive, they have a half
    life too, and were almost ready to discover what
    it is.
  • But first, we are going to do a simulation.

30
Coin Toss Activity
  • This activity will simulate the muon half-life
    data you will be collecting later.
  • Each coin represents a radioactive particle
  • When the coin comes up tails, it has decayed.
  • Keep track of how many tosses it took until the
    coin decayed (e.g. HHT would be 3 tosses until
    the coin decayed)

31
Coin Toss (cont.)
  • When making your table of surviving data, the
    pennies that survived after 1 toss are all of
    the pennies that had 2 or more tosses. Those
    that survived after 2 tosses are those that you
    tossed 3 or more times etc...
  • Graph the number surviving vs tosses

32
Linearize Graph
  • Use the log equation we found before
  • Graph log(number surviving) vs tosses
  • It should be a straight line, or close
  • Make a best fit line and find the slope
  • The half-life of a penny should be one toss

33
Muon Half-Life
  • Now we are ready to find the half-life of a muon

34
Cosmic Ray Detectors
  • A cosmic ray detector consists of two parts, the
    scintillator, and the photomultiplier tube (PMT)
  • Scintillator is a special plastic that emits
    light when a cosmic ray goes through it
  • A PMT detects that light and sends a signal to
    the computer, indicating a cosmic ray has gone
    through

35
Equipment
  • The setup for this experiment consists of a shmoo
    (a chicos cosmic ray detector) on top of two
    other detectors, called paddles

36
How it works
  • The paddles are used to get a count of the
    particles that go into the shmoo, but do not go
    through the paddles
  • Most muons pass right through the shmoo and the
    paddles, but if they stop inside the shmoo, they
    will decay into electrons
  • When this decay happens, it produces two
    sequential flashes of light, and the computer can
    measure the time between them

37
Get the data
  • The data is available online at lt gt
  • Go and download a unique set of data
  • Copy your data into the spreadsheet

38
Use the excel sheet
  • This time the sheet is doing all the work you did
    for the coin toss experiment.
  • It finds the number surviving and plots it vs
    time
  • The sheet then linearizes the graph and
    calculates the half-life from the slope of the
    line
  • Now you have found the half-life of a muon.
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