ge 11a, 2014, lecture 3 radioactivity and quantitative geochronology
TRANSCRIPT
Ge 11a, 2014, Lecture 3Radioactivity and quantitative geochronology
Radioactive decay
Marie Skłodowska-CurieExplored spontaneous radioactivityShockingly dangerous chemical separations to isolate and study heavy radioactive elementsMajor innovator of radiological medicine
First woman to Win a Nobel prize (physics) Win another Nobel prize (chemistry) (first human to win two…) Teach at the Sorbonne Be enshrined in the Paris Pantheon
Trained in Poland’s underground ‘Flying University’Transformative figure in women’s +minority’s rights
Antoine Henri BecquerelDiscovered spontaneous radioactivity
Ernest Rutherford, 1st Baron Rutherford of NelsonSynthesis of radioactive decaCreated experimental nuclear physicsFirst dates of geological materials
• Rutherford recognized three types of radioactivity:
emits mass but no charge (4He nucleus)
emits charge but no (observable) mass (electron or positron)
emission has neither charge nor mass (high-frequency radiation)
• Realizes radiactivity has two key properties:- exothermic- some forms emit particles (a = 4He) that might accumulate as record
of the passage of time
• Postulates that rate of emission is independent of environment, history, etc. It is intrinsic & probabilistic.
The most well reasoned forms of creation science question this hypothesis. They are right to do so (though all experiments and nuclear theories to-date suggest it is a good approximation in geological environments)
If rate of emission is invariant w/ time or setting, then radiation can serve as a clock:
- dN/dt = N
Constant of proportionality; now called ‘decay constant’
1/ = ‘mean life’ln2/ = ‘half life’
(a miracle of integration occurs)
N = N0e-t
For and radiation, nothing lasting is produced (at least, nothing detectable by 1900-era scientists). But particles accumulate in a measurable way:
Define ‘D’ as number of ‘daughter’ particles
D = D0 + D*D* = N0 - ND = N0(1-e-t) + D0 = N (et-1) + D0
Re-arrange decay equation to make time the dependant variable:
ln {[ (D-D0)N
] +1}
t =
Pick mineral with no structural He; D0 = 0
Radiation counting in lab
Pick mineral w/ stoichiometric Parent element (e.g., UO2), soN depends only on mass
With correct choice of sample, t depends only on D - the amount of He trapped in the mineral lattice
Rutherford’s chronometer
Pitchblende, or U ore, rich in UO2
U ~ 1.5x10-10
U 8
Time (yrs) moles He cc STP1000 5x10-9 1x10-4
1 million 5x10-6 0.110 million 5x10-5 1.01 billion 5x10-3 100
1 gram of UO2
Found African pitchblende is ca. 500 million years old
Problems:• Sensitivity and precision of manometric measurements• Reaction is not fully described. U weighs ca. 238 g/mol; 8 He nuclei only 32 g/mol. Where is the rest of the mass!• He is not well retained by crystals
Breakthrough: Aston’s positive ray device
Ions are passed through a magnetic field oriented orthogonalTo their direction of motion. Ions are deflected with a radius of curvature set by the force balance between the magnetic field (qv x B) and the centripital force (mv2/r). That is, r = mv/(qB)
If energy is of all ions is equal, this acts as a mass filter.
High momentum(high mass)
Low momentum(low mass))
Intensity
Strength of B field
Finnigan TritonA modern thermal ionization mass spectrometer
Ion source
Collectors (faraday cupsand/or electron multipliers)
Momentum analyzer (electro magnet)
Advances stemming from mass spectrometry• Precision improves from ca. ±1 % to ca. ±10-5
• Recognition of isotopes permits the definition of decay reactions
Zprotons + Nneutrons = Amass
decay: Z + N (Z-2) + (N-2) + 4He + + Qe.g., 238U 234Th + 4He; = 1.55x10-10
147Sm 143Nd + 4He; = 6.5x10-12 yr-1
decay: Z + N (Z+1) + (N-1) + e- + + Qe.g., 87Rb 87Sr + e-; = 1.42x10-11 yr-1
decay: Z + N (Z-1) + (N+1) + e+ + + Qe.g., 18F 18O + e+; = 3.3x103 yr-1
Most geological ‘chronometers’ depend on and decay
e.g., 14C 14N + e-; = 1.2x10-4 yr-1
Mass spectrometry is best at measuring relative abundances of isotopes. This motivates an additional change to age-dating equations:
D = Daughter (4He; 87Sr; 143Nd)N = Parent (238U; 87Rb; 147Sm)S = Stable (3He; 86Sr; 144Nd)
The ‘stable’ nuclide is always a non-radioactive, non-radiogeneicisotope of the same element as the ‘Daughter’ nuclide.
D = N (et - 1) + D0
D/S = N/S (et - 1) + D0/S
This is the equation for a line in the ‘isochron’ plot
Y-axis value
X-axis value
Y-interceptSlope
D/S
N/S
D0/S
m = et - 1
Measured composition of object
Three strategies for use:• Measured objects known to have D0/S ~ 0• Assume or infer D0/S from independent constraint• Define slope from two or more related objects, yielding both age (t) and D0/S as dependent variables. These objects must be of same age, have started life with identical D0/S, but differ significantly in N/S
The anatomy of the isochron diagram
A common example:the Rb-Sr chronometer applied
to granite
Isotopes of Sr:84Sr: 0.56 %86Sr: 9.87 %87Sr: 7.04 %88Sr: 82.53 %(all values approximate)
Sr: typically a +2 cation; 1.13 Å ionic radius (like Ca: +2, 0.99 Å)
Isotopes of Rb:85Rb: Stable87Rb: Radioactive: l = 1.42x10-11 yr-1;- decay
85Rb/87Rb in all substances from earth and moon assumed = 2.59265
Rb: typically a +1 cation; 1.48 Å ionic radius (like K; +1, 1.33 Å)
Isotopes of Nd:142Nd: 27.1 %143Nd: 12.2 %144Nd: 23.9 %145Nd: 8.3 %146Nd: 17.2 %(147Nd: 10.99 d half life)148Nd: 5.7 %150Nd 5.6 %(all values approximate)
Isotopes of Sm:144Sm: 3.1 %(146Sm: 108 yr half life)147Sm: 15.0 % (1.06x1011 yr half life)148Sm: 11.2 %149Sm: 13.8 %150Sm: 7.4 %(151Sm: 93 year half life)152Sm 26.7 %154Sm: 22.8 %(all values approximate)
The Sm-Nd chronometer
The ‘rare earth’ elements
Nor
mal
ized
abun
danc
e Plagioclase
Pyroxene
Garnet
A fragment of the chondritic meteorite, Allende
A thin section of the chondritic meteorite, Allende
"There is one independent check on the age of the solar system determined by radioactivity in meteorites. Detailed theoretical studies of the structure of the sun, using its known mass and reasonable assumptions about its composition, indicates that it has taken the sun about five billion years to attain its present observed radius and luminosity.”
W. Fowler
Comparison with a modern ‘Kelvinistic’ argument:
Summary of typical stellar lifetimes, sizes and luminosities
14C decay: The basis of most ages for geologically young things
14C is produced in the atmosphere: 14N + n = 14C + p
Cosmic-ray fast neutrons
Undergoes beta-decay with a half-life of 5730 yrs: 14C = 14N + e-
= 1.209x10-4 yr-1
Age (yrs) = 19,035 x log (C/C0) [ or …’x log (Activity/Activity0)’]
Key for application is assumption of a value of C0, which depends on14C/12C ratio in atmosphere
Real applications require correction for natural isotopic fractionation (e.g., during photosynthesis) and must consider variations in production rate with time and isotopic heterogeneity of surface carbon pools
The ‘bomb spike’
Natural heterogeneity: 14C ‘ages’ of deep ocean water
Variation in atmospheric 14C/12Cthrough time due to natural processes
∆14C = (Ri/R0 -1)x1000
Where Ri = 14C/12C at time of interest
R0 = 14C/12C of pre-1890 wood projected forward to 1950 (?!?&*!)
Using 14C to reconstruct earthquakerecurrence intervals
The U-Pb system and the age of the Earth
238U = 206Pb + 8x4He = 1.55125x10-10 (4.5 Ga half life)235U = 207Pb + 7x4He = 9.8485x10-10 (0.7 Ga half life)
204Pb is a stable isotope238U/235U is (nearly) constant in nature = 137.88
206Pb204Pb
207Pb204Pb
207Pb0
204Pb
206Pb0
204Pb
238U204Pb
235U204Pb
(et - 1)
(et - 1)
= +
= +
207Pb204Pb
207Pb0
204Pb206Pb204Pb
206Pb0
204Pb
-
-=
1
137.88
(et - 1)(et - 1)
K-Ar dating
40K
40Ca 40Ar88.8 % 11.2 %
e- capture; e = 0.581x10-10 yr-11e- emission; = 4.982x10-10 yr-1
40Ar = e/40K(et-1) + 40Ar0
= e + = 5.543x10-10 yr-1
0.01167 % of natural K
Some ‘closure temperatures’ w/r to K/Ar dating:
Amphibole: 500 to 700 ˚C
Biotite: 300 to 400 ˚C
K-feldspar: 200-250 ˚C