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Apatite Fission-track Analysis of Twelve Outcrop Samples from the Chandler Lake and Killik River l:250,000-scale Quadrangles, South-central North Slope, Alaskaby Thomas E. Moore 1 , David W. Houseknecht2, and Christopher J. Potter3 ,
Open-File Report 00-220
2000
This report is preliminary and has not been reviewed for conformity with U.S. Geological Survey editorial standards or with the North American Stratigraphic Code. Any use of trade, firm, or product names is for descriptive purposes only and does not imply endorsement by the U.S. Government.
U.S. DEPARTMENT OF THE INTERIOR U.S. GEOLOGICAL SURVEY
'Menlo Park, California 2Reston, Virginia 3Denver, Colorado
Moore, Houseknecht, and Potter: Apatite Fission-Track Analysis of Twelve Samples OF 00-220
INTRODUCTION
This Open-File report releases to the public the results of apatite fission-track analysis (AFTA) of twelve rock samples from the south-central North Slope of Alaska. These samples were collected by geologists of the U.S. Geological Survey from rock outcrops of Early Cretaceous age in the Killik River and Chandler Lake l:250,000-scale quadrangles during July, 1999 as part of a petroleum resource investigation of the National Petroleum
Reserve, Alaska (NPRA). The fission-track investigation was undertaken for the purpose
of determining the thermal-chronologic history of the subsurface section in NPRA.
Laboratory analysis of the samples was completed by GeoTrack Inernational on contract to
the U.S. Geological Survey. This report contains the raw data results of GeoTrack's apatite fission-track analysis without interpretation. Interpretations of the raw data released
here will be made and presented elsewhere at a later date.
The locations, the stratigraphic age, rock formation assignment, and apatite yields from
the twelve samples are present in Table 1. The analytical results of the apatite fission-track analysis are presented in Table 2 and a summary of the length distribution data is presented in Table 3. Following a discussion provided by GeoTrack of the sample preparation techniques used for the analysis, background information about the methods of determining apatite fission-track ages, and methods of reporting fission-track data, the results of the analysis are presented in individual data sheets by sample number. The data sheets include
both tabular and graphical presentations of the fission-track results. The results include fission-track ages (both individual grains and mean age), confined length measurements, and the chlorine content of each age grain.
The quality of the AFTA results reported here is excellent. Apatite yields in all samples were excellent, with all samples providing twenty or more grains for fission track age determination. The apatite grains are detrital grains of very good quality. In most samples,
the apatite grains are euhedral with a small number of rounded and angular grains observed
in all samples. Overall, the samples provided age and length data of excellent quality.
SAMPLE PREPARATION
Core and outcrop samples are crushed in a jaw crusher and then ground to sand grade in a rotary disc mill. Cuttings samples are washed and dried before grinding to sand grade.
Moore, Houseknecht, and Potter: Apatite Fission-Track Analysis of Twelve Samples OF 00-220
The ground material is then washed to remove dust, dried and processed by conventional heavy liquid and magnetic separation techniques to recover heavy minerals. Apatite grains are mounted in epoxy resin on glass slides, polished and etched for 20 sec in 5M HNOa at
20°C to reveal the fossil fission tracks.After etching, all mounts are cut down to 1.5 X 1 cm, and cleaned in detergent, alcohol
and distilled water. The mounts are then sealed in intimate contact with low-uranium
muscovite detectors within heat shrink plastic film. Each batch of mounts is stacked between two pieces of uranium standard glass which has been prepared in similar fashion. The stack is then inserted into an aluminium can for irradiation.
After irradiation, the mica detectors are removed from the grain mounts and standard glasses and etched in hydrofluoric acid to reveal the fission tracks produced by induced
fission of 235U in the apatite and standard glass.
FISSION-TRACK AGES
Fission-track ages are calculated using the standard fission track age equation using the zeta calibration method (equation 5 of Hurford and Green, 1983), viz:
F.T. AGE = f in [ 1 + ( U° Ps g PD ) ] equation 1 AD pi
where: XD = total decay constant of 238U (= 1.55125 x 1CH0)
£ = Zeta calibration factorps = Spontaneous track densitypi = Induced track density
pD = Track density from uranium standard glass
g = A geometry factor (= 0.5)Fission track ages are determined by the external detector method or EDM (Gleadow,
1981). The EDM has the advantage of allowing fission track ages to be determined on single grains. In apatite, tracks are counted in 20 grains from each mount wherever possible. In those samples where the desired number is not present, all available grains are counted, the actual number depending on the availability of suitably etched and oriented
grains. Only grains oriented with surfaces parallel to the crystallographic c-axis are analysed. Such grains can be identified on the basis of the etching characteristics, as well as from morphological evidence in euhedral grains. The grain mount is scanned sequentially, and the first 20 suitably oriented grains identified are analysed.
Moore, Houseknecht, and Potter: Apatite Fission-Track Analysis of Twelve Samples OF 00-220
Tracks are counted within an eyepiece graticule divided into 100 grid squares. In each grain, the number of spontaneous tracks, Ns, within a certain number of grid squares, Na,
is recorded. The number of induced tracks, NI, in the corresponding location within the mica external detector is then counted. Spontaneous and induced track densities, ps and pi, respectively, are calculated by dividing the track counts by the total area counted, given by
the product of Na and the area or each grid square (determined by calibration against a ruled stage graticule or diffraction grating). Fission track ages may be calculated by substituting track counts, Ns and Nj, for track densities ps and pi in equation 1, since the areas cancel
in the ratio.Translation between apatite grains in the grain mount and external detector locations
corresponding to each grain is carried out using Autoscan microcomputer-controlled
automatic stages (Smith and Leigh Jones, 1985). This system allows repeated movement
between grain and detector, and all grain locations are stored for later reference if required.
Neutron irradiations are carried out in a well thermalised flux (X-7 facility; Cd ratio for Au -98) in the Australian Atomic Energy Commission's HIFAR research reactor. Total neutron fluence is monitored by counting tracks in mica external detectors attached to two pieces of NBS standard glass SRM612 included in the irradiation canister at each end of the sample stack. In determining track densities in external detectors irradiated adjacent to
uranium standard glasses, 25 fields are normally counted in each detector, and the total
track count ND is divided by the total area counted to obtain the track density po- The
positions of the counted fields are arranged in a 5 X 5 grid covering the whole area of the
detector. For typical track densities of between ~5 X 105 and 5 X 106 this is a convenient arrangement to sample across the detector while gathering sufficient counts to achieve a precision of ~±2% in a reasonable time.
A small flux gradient is often present in the irradiation facility over the length of the sample package (note that this developed only in late 1991, after extended refurbishment of the reactor, before which no detectable flux gradient was present). If a detectable gradient
is present, the track count in the external detector adjacent to each standard glass is converted to a track density po and a value for each mount in the stack is calculated by linear interpolation. When no detectable gradient is present, the track counts in the two
external detectors are pooled to give a single value of po which is used to calculate fission
track ages for each sample.A Zeta calibration factor, £, has been determined empirically for each observer by
analysing a set of carefully chosen age standards with independently known K-Ar ages, following the methods outlined by Hurford and Green (1983) and Green (1985).
Moore, Houseknecht, and Potter: Apatite Fission-Track Analysis of Twelve Samples OF 00-220
All track counting is carried out using ZeissW Axioplan microscopes, with an overall linear magnification of 1068 x using dry objectives.
For further details and background information on practical aspects of fission track age determination, see e.g. Fleischer, Price and Walker (1975), Naeser (1979) and Hurford (1986).
TRACK-LENGTH MEASUREMENTS
For track length studies in apatite, the full lengths of 'confined' fission tracks are measured. Confined tracks are those which do not intersect the polished surface but have been etched from other tracks or fractures, so that the whole length of the track is etched. Confined track lengths are measured using a digitising tablet connected to a microcomputer, superimposed on the microscope field of view via a projection tube. With this system, calibrated against a stage graticule ruled in 2 [im divisions, individual tracks can be measured to a precision of ± 0.2 um. Tracks are measured only in prismatic grains, characterised by sharp polishing scratches with well etched tracks of narrow cone angle in all orientations, because of the anisotropy of annealing of fission tracks in apatite (as discussed by Green and others, 1986). Tracks are also measured following the recommendations of Laslett and others (1982), the most important of which is that only horizontal tracks should be measured. One hundred tracks are measured whenever possible. In apatite samples with low track density, or in those samples in which only a small number of apatite grains are obtained, fewer confined tracks may be available, and in such cases, the whole mount is scanned to measure as many confined tracks as possible.
INTEGRATED FISSION-TRACK AGE AND LENGTH MEASUREMENTS
Fission track age determination and length measurement are now made in a single pass of the grain mount, in an integrated approach. The location of each grain in which tracks are either counted or measured is recorded for future reference. Thus track length measurements can be tied to age determination in individual grains. As a routine procedure we do not measure the age of every grain in which lengths are determined, as this would be much too time consuming. Likewise we do not only measure ages in grain in which lengths are measured, as this would bias the age data against low track density grains. Nevertheless, the ability to determine the fission track age of certain grains from which
Moore, Houseknecht, and Potter: Apatite Fission-Track Analysis of Twelve Samples OF 00-220
length data originate can be a particularly useful aid to interpretation in some cases. Grain location data are not provided in this report, but are available on request.
PRESENTATION OF FISSION-TRACK AGE DATA
Data sheets summarising the apatite fission track age data, including full details of fission track age data for individual apatite grains in each sample, together with the primary counting results and statistical data, are given in the following pages. Individual grain fission track ages are calculated from the ratio of spontaneous to induced fission track counts for each grain using equation 1, and errors in the single grain ages are calculated using Poissonian statistics, as explained in more detail by Galbraith (1981) and Green (1981). All errors are quoted as ±lc throughout this report, unless otherwise stated.
The variability of fission track ages between individual apatite grains within each sample can be assessed using a chi-squared (%2) statistic (Galbraith, 1981), the results of which are summarised for each sample in the data sheets. If all the grains counted belong to a single age population, then the probability of obtaining the observed %2 value, for v degrees of freedom (where v = number of crystals -1), is listed in the data sheets as P(%2) or P(chi squared).
A P(%2) value greater than 5% can be taken as evidence that all grains are consistent with a single population of fission track age. In this case, the best estimate of the fission track age of the sample is given by the "pooled age", calculated from the ratio of the total spontaneous and induced track counts in all grains analysed. Errors for the pooled age are calculated using the 'conventional' technique outlined by Green (1981), based on the total number of tracks counted for each track density measurement (see also Galbraith, 1981).
A P(5C2) value of less than 5% denotes a significant spread of single grain ages, and suggests that real differences exist between the fission track ages of individual apatite grains. A significant spread in grain ages can result either from inheritance of detrital grains from mixed source areas (in sedimentary rocks), or from differential annealing in apatite grains of different composition, within a narrow range of temperature.
Calculation of the pooled age inherently assumes that only a single population of ages is present, and is thus not appropriate to samples containing a significant spread of fission track ages. In such cases Galbraith has recently devised a means of estimating the modal age of a distribution of single grain fission track ages which is referred to as the "central age". Calculation of the central age assumes that all single grain ages belong to a Normal distribution of ages with a standard deviation, a, known as the "age dispersion". An iterative algorithm (Galbraith and Laslett, 1993) is used to provide estimates of the central
Moore, Houseknecht, and Potter: Apatite Fission-Track Analysis of Twelve Samples OF 00-220
age with its associated error, and the age dispersion, which are all quoted in the data sheets.
Note that this treatment replaces use of the "mean age" which has used been in the past for
those samples in which P(x2)<5%. For samples in which P(x2)>5%, the central age and the pooled age should be equal, and the age dispersion should be less than ~10%.
Table 2 summarises the fission track age data in apatite from each sample analysed.
CONSTRUCTION OF RADIAL PLOTS OF SINGLE GRAIN AGE DATA
Single grain age data are best represented in the form of radial plot diagrams (Galbraith,
1988,1990). As illustrated in Figure 1, these plots display the variation of individual grain
ages in a plot of y against x, where:y = (zj - z0) /Oi x = 1/Oj equation 2
and; Zj = fission track age of grain j z0 = a reference age Oj = error in age for grain j
In this plot, all points on a straight line from the origin define a single value of fission
track age, and at any point the value of x is a measure of the precision of each individual
grain age. Therefore, precise individual grain ages fall to the right of the plot (small error, high x), which is useful, for example, in enabling precise, young grains to be identified. The age scale is shown radially around the perimeter of the plot (in Ma). If all grains belong to a single age population, all data should scatter between y = +2 and y = -2,
equivalent to scatter within ±2o. Scatter outside these boundaries shows a significant spread of individual grain ages, as also reflected in the values of P(X2) and age dispersion.
In detail, rather than using the fission track age for each grain as in equation 2, we use:Nsi
Zj = j^r GJ ={ l/Nsj+ l/Ny} equation 3
as we are interested in displaying the scatter within the data from each sample in
comparison with that allowed by the Poissonian uncertainty in track counts, without the
additional terms which are involved in determination of the fission track age (pD, £, etc).
Zero ages cannot be displayed in such a plot. This can be achieved using a modified plot, (Galbraith, 1990) with:______ _________
/ f Nsj+3/8 l 1 If I f z\=arcsin\l 1 vr . , vj.. j. *IA I <Ji = T v 1 vr . _,_ xr . i eq. 4
Moore, Houseknecht, and Potter: Apatite Fission-Track Analysis of Twelve Samples OF 00-220
Note that the numerical terms in the equation for Zj are standard terms, introduced for statistical reasons. Using this arc-sin transformation, zero ages plot on a diagonal line which slopes from upper left to lower right. Note that this line does not go through the origin. Figure 2 illustrates this difference between conventional and arc-sin radial plots, and also provides a simple guide to the structure of radial plots.
Use of arc-sin radial plots is particularly useful in assessing the relative importance of zero ages. For instance, grains with Ns = 0, NI = 1 are compatible with ages up to ~900 Ma (at the 95% confidence level), while grains with Ns = 0, NI = 50 are only compatible with ages up to ~14 Ma. The two data would readily be distinguishable on the radial plot as the 0,50 datum would plot well to the right (high x) compared to the 0,1 datum.
In this report the value of z corresponding to the fission track age of each sample is adopted as the reference value, z0 .
Note that the x axis of the radial plot is normally not labelled, as this would obscure the age scale around the plot. In general labelling is not considered necessary, as we are concerned only with relative variation within the data, rather than absolute values of precision.
Radial plots of the single grain age data in apatite from each sample analysed in this report are shown on the fission track age data summary sheets at the end of this report.
HISTOGRAMS OF TRACK-LENGTH DATA
Distributions of confined track lengths in apatite from each sample are shown as simple histograms on the fission track age data summary sheets at the end of this report. For every track length measurement, the length is recorded to the nearest 0.1 urn, but the measurements have been grouped into 1 um intervals for construction of these histograms. Each distribution has been normalised to 100 tracks for each sample to facilitate comparison. A summary of the length distribution in each sample is presented in Table 3, which also shows the mean track length in each sample and its associated error, the standard deviation of each distribution and the number of tracks (N) measured in each sample. The angle which each confined track makes with the crystallographic c-axis is also routinely recorded, as is the width of each fracture within which tracks are revealed. These data are not provided in this report.
BREAKDOWN OF DATA INTO COMPOSITIONAL GROUPS
Moore, Houseknecht, and Potter: Apatite Fission-Track Analysis of Twelve Samples OF 00-220
Apatite fission-track data are grouped into compositional intervals of 0.1 wt% Cl width. Parameters for each interval represent the data from all grains with Cl contents within each interval. Also shown are the parameters for each compositional interval predicted from the Default Thermal History. These data form the basis of interpretation of the AFTA data,
which takes full account of the influence of Cl content on annealing kinetics. Distributions
of Cl contents in all apatites analysed from each sample (i.e. for both age and length determinations) are shown on the fission-track age data summary sheets at the end of this
report.
PLOTS OF FISSION-TRACK AGE AGAINST Cl CONTENT FOR INDIVIDUAL APATITE GRAINS
Fission-track ages of single apatite grains within individual samples are plotted against the Cl content of each grain on the fission-track age data summary sheets at the end of this report. These plots are useful in assessing the degree of annealing, as expressed by the fission-track age data. For example, if grains with a range of Cl contents from zero to
some upper limit all give similar fission-track ages which are significantly less than the
stratigraphic age, then grains with these compositions must have been totally annealed.
Alternatively, if fission-track age falls rapidly with decreasing Cl content, the sample displays a high degree of partial annealing.
A NOTE ON TERMINOLOGY
Note that throughout this report, the term "fission-track age" is understood to denote the
parameter calculated from the fission-track age equation, using the observed spontaneous
and induced track counts (either pooled for all grains or for individual grains). The resulting number (with units of Ma) should not be taken as possessing any significance in
terms of events taking place at the time indicated by the measured fission-track age, but should rather be regarded as a measure of the integrated thermal history of the sample, and should be interpreted in that light. Use of the term "apparent age" is not considered to be
useful in this regard, as almost every fission-track age should be regarded as an apparent age, in the classic sense, and repeated use becomes cumbersome.
Moore, Houseknecht, and Potter: Apatite Fission-Track Analysis of Twelve Samples
Estimates z.
Standard errors G;Reference value zoStandardised estimates y. = (
Precision x. = 1
OF 00-220
PLOT y. against x-
y:
+2 +1
0-1-2
Z;
z -
X.
Slope of line from origin through data point
= 7-71 O
Key Points;Radial lines emanating from the origin correspond to fixed values of z Data points with higher values of Xj have greater precision. Error bars on all points are the same size in this plot.
Figure 1. Basic construction of a radial plot. In AFTA, the estimates z[ correspond to the fission-track age values for individual apatite grains. Any convenient value of age can be chosen as the reference value corresponding to the horizontal in the radial plot. Radial lines emanating from the origin with positive slopes correspond to fission-track ages greater than the reference value. Lines with negative slopes correspond to fission- track ages less than the reference value.
Moore, Houseknecht, and Potter: Apatite Fission-Track Analysis of Twelve Samples
Normal radial plot (equations 2 and 3)
OF 00- 220
^
Allowed 'range for a single population '
+210 i
r -2
\"
L LtSb ____ _ MORE
>. PRECISE"* ̂ PRECISE
°\ / YOUNGER ~~/
*
^ _ Reference age
0
Arc-sin radial plot (equations 2 and 4)
Allowed ' range for a single population <
, +2
0
r -2
^
\.DER
Is Lbbb ^ __ ___ ̂MORE s s PRECISE"* ̂PRECISE
\ /S yr
S ^ s y/ YOUNGER
%
^ _ Reference age
Figure 2 Simplified structure of Normal and Arc-sin radial plots.
10
Moore, Houseknecht, and Potter: Apatite Fission-Track Analysis of Twelve Samples OF 00- 220
Table 1. Fission-track sample numbers, locations, stratigraphic assignment, age, and apatite yields for analyzed samples. Stratigraphic ages from Micropaleo Consultants, Inc._______________
Sample USGS field Location and number Number Elevation (ft)
Stratigraphic Subdivision
Stratigraphic Raw Washed Apatiteage weight weight yield *l
(Ma) (g) (g)
Outcrop samplesGC763-36 99TM-503B
GC763-37 99TM-515B
GC763-38 99TM-538
GC763-39 99TM-551B
GC763-40 99TM-564B
GC763-41 99TM-568A
GC763-42 99TM-576B
GC763-43 99TM-578B
GC763-44 99DH-52
GC763-45 99DH-54
GC763-46 99DH-65B
GC763-47 99CP-A13
Okokmilaga at Akmaktaksrak Bluff 68°37.513'N 153°13.650'W 1640'
Siksikpuk Rv at Tiglukpuk Ck 68031.911'N 152002.981'W 1500'
Gunsight Mtn 68°42.820' N 151°52.092'W 450'
Okpikruak Rv at Sivogakruak Bluff 68.66894° N 153.45382° W 1542'
Kiruktagiak Rv 68°37.666' N 152°39.349'W 1500'
Tiglukpuk Ck 68°25.943' N 151°54.091'W 200'
Pediment Ck 68°42.347' N 153°13.854'W 1345'
junction of Killik - Okokmilaga Rvs 68°55.728' N 153°26.058'W 869'
trib. To E fork, Oolamnagavik Rv 68.78355°N 153.96614°W 1200'
Killik bend, Colville Rv 68.97000°N 153.94053° W 600'
Okpikruak Rv at Sivogakruak Bluff 68°40.452' N 153°25.987'W 1476'
Siksikpuk Rv near Confusion Ck 68°28.060' N 152°05.216'W 2000'
Fortress Mtn Fm
Fortress Mtn Fm
Tuktu Fm
Torok Fm
Fortress Mtn Fm
Okpikruak
Torok Fm
Chandler Fm
Torok Fm
Chandler Fm
Torok Fm
Okpikruak Fm
115-105 4580 660 excellent
115-105 5000 640 excellent
110-100 6750 550 excellent
112-105 6070 790 excellent
115-105 6530 590 excellent
141-136 5760 800 excellent
112-105 4210 990 excellent
90-84 5450 540 excellent
112-105 9040 1790 excellent
90-84 5670 1580 excellent
112-105 5240 1390 excellent
141-136 2870 880 excellent
Yield based on quantity of mineral suitable for age determination. Excellent: >20 grains; Good: 15-19 grains; Fair: 10-14 grains; Poor: 5-9 grains; Very Poor: <5 grains. 11
Moore, Houseknecht, and Potter: Apatite Fission-Track Analysis of Twelve Samples
Table 2. Apatite fission-track analytical results.
OF 00- 220
Sample number
Outcrop samplesGC763-36
GC763-37
GC763-38
GC763-39
GC763-40
GC763-41
GC763-42
GC763-43
GC763-44
GC763-45
GC763-46
GC763-47
Number of
grains
27
25
34
25
29
31
23
26
25
20
25
29
PD(ND)
x!06 /cm2
1.397(2253)1.403
(2253)
1.409(2253)
1.415(2253)
1.420(2253)1.426
(2253)
1.432(2253)
1.438(2253)1.444
(2253)
1.450(2253)1.455
(2253)
1.461(2253)
PS(Ns)
x!06 /cm2
0.569(383)0.459(513)
0.497(439)
0.437(355)0.553(580)0.397(389)
0.621(244)
0.395(331)0.711(408)0.061(36)0.656(409)0.336(328)
P'(Ni)
x!06 /cm2
2.367(1594)2.104(2350)
1.955(1727)
1.764(1434)1.736
(1821)1.776
(1742)
2.592(1018)
1.059(888)2.539(1457)0.402(239)2.433(1517)1.527
(1491)
Uranium content
(ppm)
19
17
16
14
14
14
21
8
20
3
19
12
P(%2 )
(%)
90
<1
1
5
<1
<1
65
<1
<1
1
<1
3
Age dispersion
(%)
<1
36
30
18
27
31
2
46
36
124
40
26
Fission track age
(Ma)
63.9 ±4.0
58.3 ±3.258. 9 ±5.9*68.1 ±4.064.8 ±6.1*66.6 ±4.369. 1 ±5.6*85.9 ±4.686. 1 ±7.6*60.6 ± 3.764.2 ±6.1*65.3 ±4.9
101.7 ±7.089.8 ±13.6*76.8 ±4.775.9 ±8.1*41.6 ±7.5
33.2 ±12.9*74.6 ±4.6
97.2 ±10.4*61.2 ±4.060.2 ±'5.3*
p s = spontaneous track density; P i = induced track density; P D = track density in glass standard external detector. Brackets show number of tracks counted. P D and P i measured in mica external detectors; p s measured in internal surfaces. *CentraI age, used where sample contains a significant spread of single grain ages (P(^)<5%). Errors quoted at 10. Ages calculated using dosimeter glass CN5, with a zeta of 382.4 ± 5.5 (Analyst: S. Marshallsea) for samples; 36 - 47
12
Moore, Houseknecht, and Potter: Apatite Fission-Track Analysis of Twelve Samples
Table 3. Length distribution summary data.
OF 00- 220
Sample number
Mean track length
(urn)
Outcrop samplesGC763-36 13.59 ±0.18GC763-37GC763-38GC763-39GC763-40GC763-41GC763-42GC763-43GC763-44 GC763-45 GC763-46GC763-47
13.36 ±0.2212.78 ± 1.9313.70 ±0.2614.37 ±0.2113.88 ±0.1813.50 + 0.2413.21+0.4013.80 ±0.21 No confined 13.39 ±0.2214.26 ±0.19
Standard deviation
1.692.161.931.991.461.84
2.212.252.08
tracks 2.031.67
Number of tracks
(N)
851002258481088532101
8477
Number of tracks in Length Intervals (urn) 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16
------- 2 2 3 7
- - - - 1 1 - 2 - 4 1........ 1 . 1-------- 1 2 3--..-..... 1-------- 1 6 2
- - 1 1 ----- 1 2......... 4 4
- - - - 1 - - 1 3 2 1
... 1 ... 1 . 2 7
.......... 2
12735287-
6
49
181737611
946
117
2231512112124
622
199
17168109
2825635
2522
211-
11132210616
1217
17 18 19 20
6 3 - -1 ...7 ...6 ...9 ...
5 - - -2 - - -7 1 - -
1 1 - -11 ...
Track length measurements by: S. Marshallsea for samples; 36 - 47
13
Moore, Houseknecht, and Potter: Apatite Fission-Track Analysis of Twelve Samples OF 00-220
EXPLANATION FOR FISSION-TRACK DATA SHEETS
Ns = Number of spontaneous tracks in Na grid squaresNi = Number of induced tracks in Na grid squaresNa = Number of grid squares counted in each grainRATIO = Ns/NiU (ppm) = Uranium content of each grain (= U content of standard glass *
pi/PD) Cl (wt%) = Weight percent chlorine content of each grain
RHOs = Spontaneous track density (ps) = Ns/ (Na*area of basic unit)
RHOi = Induced track density (pi) = Ni/(Na*area of basic unit) F.T. AGE = Fission-track age, calculated using equation 1 Area of basic unit = Area of one microscope eyepiece grid square
Chi squared = %2 parameter, used to assess variation of single grain ages within the sample
P(chi squared) = Probability of obtaining observed %2 value for the relevant number of degrees of freedom, if all grains belong to a single population
Age Dispersion = % variation in single grain ages - see discussion in text re "Central age"
Ns/Ni = Pooled ratio, total spontaneous tracks divided by total induced tracks for all grains
Mean ratio = Mean of (Ns/Ni) for individual grainsZeta = Calibration constant, determined empirically for each observer
RhoD = Track density (p£>) from uranium standard glass (interpolated from values at each end of stack)
ND = Total number of tracks counted for determining pj) POOLED AGE = Fission-track age calculated from pooled ratio Ns/Ni. Valid only
when %2 > 5%
CENTRAL AGE = Alternative to pooled age when %2 < 5%
14
Moore, Houseknecht, and Potter: Apatite Fission-Track Analysis of Twelve Samples OF 00-220
Organization and captions for graphical plots shown in data sheets:
Plot A: Radial plot of single grain ages for analyzed sample.(See Figures 1 and 2 for details of radial plot construction)
Plot B: Distribution of Cl contents in apatite grains for analyzed sample.
Plot C: Single grain age vs weight % Cl for individual apatite grains in analyzed sample
Plot D: Distribution of confined track lengths in analyzed sample.
15
Moore, Houseknecht, and Potter: Apadte Fission-Track Analysis of Twelve Samples GC763-36 APATITE IRRADIATION G820 TTOr'O c« i~ (uvrnv/r cniSLIDE NUMBER i USlrS Sample 99TM-503COUNTED-BY: SJM
OF 00-220 99TM-503B
Current grain no.
3412131518212225293031323334373941434448495253627379
Ns
12132
3218104261429
266817311541
25232862166
Ni
6658168971841196
27621038893854871297385
11269982708124
Na
422442204420602824162032324819505040705030404880306348
RHOs
4.540E4058.607E4057.567E+042.542E+063.612E+046.356E4052.648E4052.270E4051.324E4055.959E4051.112E+069.932E+044.469E4058.607E4055.018E4052.542E4055.403E4051.232E+063.405E4051.271E4055.297E+049.932E+057.614E4055.562E4053.284E+064.036E4051.986E405
RHOi
2.497E+063.840E+066.054E+057.071E+062.528E4051.430E+061.086E+061.078E4063.973E4052.682E+064.926E+064.966E4051.887E+062.946E+063.178E+061.716E+062.765E+065.125E+061.657E+062.542E4052.648E+054.449E+062.284E+061.947E+061.430E+072.043E+067.945E+05
RATIO
0.1820.2240.1250.3600.1430.4440.2440.2110.3330.2220.2260.2000.2370.2920.1580.1480.1950.2400.2050.5000.2000.2230.3330.2860.2300.1980.250
U (ppm)
20.431.34.9
57.72.1
11.78.98.83.2
21.940.24.1
15.424.025.914.022.641.813.52.12.2
36.318.615.9
116.716.76.5
a(wt%)
0.000.060.050.060.510.210.440.020.020.020.130.350.720.000.230.000.070.050.000.490.650.570.040.200.270.010.01
F.T. AGE (Ma)
48.4 ± 15.259.6 ± 18.433.3 ± 25.095.3 ± 19.838.1 ± 40.7
117.7± 50.164.8 ± 22.956.0 ± 30.888.4 ± 72.259.1 ± 26.760.0 ± 17.853.2 ± 41.263.0 ± 23.477.6 ± 17.442.0 ± 18.539.5 ± 15.052.0 ± 13.863.9 ± 12.954.7 ± 15.6
132.2± 81.053.2 ± 58.359.4 ± 13.288.4 ± 21.475.9 ± 16.461. 1± 8.752.6 ± 14.466.4 ± 30.4
383 1594 5.688E+05 2.367E+06 19.3
Area of basic unit = 6.293E-07 cm-2
Chi Squared = 17.322 with 26 degrees of freedomP(chi squared) = 89.9 %Age Dispersion = 0.295 % (did not converge)Ns/Ni= 0.240 ± 0.014Mean Ratio = 0.245 ± 0.017
Ages calculated using a zeta of 382.4 ± 5.5 for CN5 glass Rho D = 1.397E+06cm-2; ND = 2253Rho D interpolated between top of can; Rho D = 1.397E+06cro-2, ND = 1099
bottom of can; Rho D= 1.467E+06cm-2, ND = 1154
POOLED AGE = 63.9 ± 4.0 MaCENTRAL AGE = 63.9 ± 4.0 Ma
A:
+2+1
0-1
-2
53
20
15
10
5
0.5 1.0 1.5 2.0 2.5 3.0 Wt % Chlorine
C: D:
300
stratigraphic age range
40
30
20
10
0.4 0.6 0.8 1 Weight % Chlorine
1.2 1.4 5 10 15 20 TRACKLB4GTH (microns)
16
Moore, Houseknecht, and Potter: Apatite Fission-Track Analysis of Twelve Samples GC763-37 APATITE
OF 00-22099TM-515B
IRRADIATION G820 SLIDE NUMBER 2 COUNTED BY: SJM
USGS Sample 99TM-515B
Current grain no.
45689101112131415161719212223
2831364448545758
Ns
144351
483
214612346
212562
665
84511851851
Ni
266185113
2092561157594651389136439
32159
369207593673
278
Na
100509039566470427074677010049848080901005070100804060
RHOs
2.225E-K)51.271E-K)55.297E+042.037E-K)52.838E+041.192E+066.810E+047.945E-K)59.080E+041.288E+052.846E+057.718E-K)59.534E+046.810E+054.729E-K)51.192E-K)53.973E+041.165E+067.945E+042.670E+061.158E+062.860E-K)59.932E+047.151E-K)51.351E+06
RHOi
4.132E-K)51.907E+053.178E-K)52.078E+063.689E-K)55.189E+065.675E+052.308E+063.405E-K)51.611E+062.229E+061.476E+062.066E-K)52.886E+062.573E+068.541E+051.788E-K)55.668E+069.375E+051.173E+074.699E+069.375E-K)57.151E-K)52.900E+067.363E+06
RATIO
0.5380.6670.1670.0980.0770.2300.1200.3440.2670.0800.1280.5230.4620.2360.1840.1400.2220.2060.0850.2280.2460.3050.1390.2470.183
U (ppm)
3.41.52.6
16.93.0
42.24.6
18.82.8
13.118.112.01.7
23.520.96.91.5
46.17.6
95.338.27.65.8
23.659.8
a(wt%)
1.051.240.280.010.000.030.260.000.020.000.141.040.500.030.060.500.670.060.060.770.090.570.050.070.30
FT. AGE (Ma)
142.9± 47.5176.4 ±114.044.6 ± 27.826.2 ± 12.320.6 ± 21.461.3 ± 9.932.1 ± 19.691.7± 23.371. 1± 40.121.4± 9.134.2 ± 10.5
138.8± 29.6122.6± 60.663.0 ± 15.449.1 ± 10.837.3 ± 16.359.3 ± 46.454.9 ± 7.622.7 ± 10.660.8 ± 7.565.8 ± 10.481.3± 22.037.2 ± 17.865.8 ± 17.449.0 ± 7.6
513 2350 4.593E-K)5 2.104E+06 17.1
Area of basic unit = 6.293E-07 cm-2
Chi Squared = 61.083 with 24 degrees of freedom P(chi squared) = 0.0 % Age Dispersion = 35.928 %
Ns/Ni= 0.218 ± 0.011 Mean Ratio = 0.245 ± 0.031
Ages calculated using a zeta of 382.4 ± 5.5 for CN5 glass RhoD= 1.403E+06cm-2; ND= 2253Rho D interpolated between top of can; Rho D = 1.397E+06cm-2. ND = 1099
bottom of can; Rho D = 1.467E+06cm-2, ND = 1154
POOLED AGE = 58.3 ± 3.2 Ma CENTRAL AGE = 58.9 ± 5.9 Ma
A:
+2+10
-1
-2
176
20
OURANQO 20 APATITE
0.5 1 .0 1.5 2.0 2.5 3.0 Wt % Chlorine
C: D:
300
<'
. stratigraphic age range _
40
30
20
10
0.2 0.4 0.6 0.8 1 1.2 1.4 Weight % Chlorine
5 10 15 20 TRACKLB4GTH (microns)
17
Moore, Houseknecht, and Potter: Apatite Fission-Track Analysis of Twelve Samples
USGS Sample 99TM-538
OF 00- 220
GC763-38 APATITE
IRRADIATION G820 SLIDE NUMBER 3 COUNTED BY: SJM
99TM-538
Current grain no.
4579101112131417182021222529303132353738394041425153434647485058
Ns
2020006710010735408
366
7425841002038243
294
319
Ni
5313232172034333
27920312
4311626
337117207139
1591228912794411056
Na
315624301550142040707010080181834802424287071282880722428253642252128
RHOs
1.025E+05O.OOOE-fOO1.324E+05O.OOOE-fOOO.OOOE-fOOO.OOOE-fOO6.810E+055.562E+053.973E404O.OOOE+OOO.OOOE-fOO1.589E404O.OOOE-fOO6.180E+052.648E+052.337E+057.945E404O.OOOE-fOO5.297E4052.043E4061.362E4051.656E4061.419E+064.767E+061.986E+05O.OOOE-fOO1.324E+062.157E+061.526E+061.324E+051.097E+062.542E+052.346E4065.108E405
RHOi
2.563E+058.513E+048.607E+051.059E+053.178E4056.356E+041.930E+061.589E+061.192E4059.080E4046.810E+044.767E4045.959E+042.384E+067.945E4059.347E4056.158E+051.324E4052.847E+066.583E+065.902E4057.542E+066.640E+061.175E+072.761E+062.207E+043.906E+066.924E+065.657E+065.297E+052.989E+062.797E+068.324E+063.178E+06
RATIO
0.4000.0000.1540.0000.0000.0000.3530.3500.3330.0000.0000.3330.0000.2590.3330.2500.1290.0000.1860.3100.2310.2200.2140.4060.0720.0000.3390.3110.2700.2500.3670.0910.2820.161
U (ppm)
2.10.77.00.92.60.5
15.612.91.00.70.60.40.5
19.36.47.65.01.1
23.053.34.8
61.053.795.122.30.2
31.656.045.84.3
24.222.667.425.7
a(wt%)
0.000.000.070.000.000.000.020.030.000.000.000.000.000.120.300.020.320.000.030.150.410.010.070.250.010.000.030.170.120.320.120.140.070.13
FT. AGE (Ma)
106.9 ± 89.40.0 ± 0.0
41.3 ± 31.40.0 ± 0.00.0 ± 0.00.0 ± 0.0
94.4 ± 44.993.6 ± 41.289.2 ± 103.0
0.0 ± 0.00.0 ± 0.0
89.2 ± 103.00.0 ± 0.0
69.5 ± 29.589.2 ± 59.567.0 ± 33.534.7 ± 18.40.0 ± 0.0
49.9 ± 19.383.1 ± 16.061.9 ± 28.158.9 ± 7.757.3 ± 12.7
108.4 ± 14.319.4 ± 6.40.0 ± 0.0
90.7 ± 23.683.4 ± 15.672.2 ± 16.767.0 ± 43.398.1 ± 21.524.4 ± 12.875.5 ± 15.543.1 ± 15.5
439 1727
Area of basic unit = 6.293E-07 cra-2
4.969E405 1.955E+06 15.8
Chi Squared = 55.127 with 33 degrees of freedom P(chi squared) = 0.9 % Age Dispersion = 29.717 %
Ns/Ni= 0.254 ± 0.014 Mean Ratio = 0.194± 0.024
Ages calculated using a zeta of 382.4 ± 5.5 for CN5 glass RhoD= 1.409E+06cm-2; ND= 2253RhoD interpolated between top of can; RhoD= 1.397E+06cm-2, ND = 1099
bottom of can; RhoD= 1.467E+06cm-2, ND = 1154
POOLED AGE = 68.1 ± 4.0 Ma CENTRAL AGE = 64.8 ± 6.1 Ma
18
Moore, Houseknecht, and Potter: Apatite Fission-Track Analysis of Twelve Samples OF 00- 220
USGS Sample 99TM-538 (continued)
GC763-38 APATITE CONTINUED 99TM-538
A:
42
+10
1-2
C:
300
OJ
S
0200< j*
S
§ 1 °°:COw
u_
0 i
C
l\
f
i 1 1
)
*bm
s«
f*1
0.2
90
1 i
0
*~D
^
"^ -
D
\1 22
r ... stratigraphic age range
I
1 1 I 1 I ! I I I
4 0.6 0.8 1 1.2 Weioht % Chlorine
11
88
66
44
1
0
4
B:
20""'D:
40
N
30
20
10
APATITE
1
11
1
1
1
ll0.5 1.0 1.5 20 2.5 3.0
Wt '/.Chlorine
-
- Jill, nr! n ,5 10 15 20
TRACK LB4GTH (microns)
19
Moore, Houseknecht, and Potter: Apatite Fission-Track Analysis of Twelve Samples OF 00- 220 GC763-39 APATITE 99TM-55IB
IRRADIATION G820 SLIDE NUMBER 4 COUNTED BY: SJM
USGS Sample 99TM-551B
Current grain no.
356791011121314161719202122232527283135633738
Ns
12211503165
, 249301138132324181127653410
Ni
818102864154985
24911220151671101116
655118722910842
Na
42164920425056502080803680804990842420543280564260
RHOs
3.783E4041.986E+056.486E4048.740E+051.892E+05O.OOOE-fOO8.513E4045.085E+053.973E+053.973E4049.733E+051.324E+062.185E+055.959E4042.594E+052.295E+054.351E+051.324E+053.178E+055.297E4055.462E+055.363E+051.844E+061.286E+062.648E405
RHOi
3.027E+051.788E+063.243E+052.225E+062.270E+051.271E+054.256E+051.557E+066.356E+059.932E4044.946E+064.944E+063.973E+052.980E+055.189E+051.254E+061.911E+067.283E+054.767E+051.913E+062.533E+063.714E+066.498E+064.086E+061.112E+06
RATIO
0.1250.1110.2000.3930.8330.0000.2000.3270.6250.4000.1970.2680.5500.2000.5000.1830.2280.1820.6670.2770.2160.1440.2840.3150.238
U (ppm)
2.414.42.6
17.91.81.03.4
12.55.10.8
39.939.83.22.44.2
10.115.45.93.8
15.420.429.952.432.99.0
a(wt%)
0.000.000.340.010.340.000.360.180.110.110.080.071.190.010.000.090.050.100.700.120.040.010.040.150.48
FT. AGE (Ma)
33.7 ± 35.830.0 ± 22.453.9 ± 41.8
105.4 ± 37.6221.6 ±134.3
0.0 ± 0.053.9 ± 34.187.7 ± 25.4
166.9 ± 95.2107.3 ± 89.853.0 ± 8.472.0 ± 14.9
147. 1± 55.353.9 ± 34.1
133.8 ± 58.149.3 ± 14.961.3 ± 14.249.0 ± 37.7
177.9 ±114.974.5 ± 19.958.1 ± 19.438.9 ± 8.176.3 ± 10.984.6 ± 16.864. 1± 22.6
355 1434 4.366E+05 1.764E+06 14.2
Area of basic unit = 6.293E-07 cm-2
Chi Squared = 36.813 with 24 degrees of freedom P(chi squared) = 4.6 % Age Dispersion = 17.626 %
Ns/Ni= 0.248 ± 0.015 Mean Ratio = 0.306 ± 0.039
Ages calculated using a zeta of 382.4 ± 5.5 for CN5 glass RhoD= 1.415E+06cm-2; ND= 2253Rho D interpolated between top of can; Rho D = 1.397E+06cm-2, ND = 1099
bottom of can; Rho D = 1.467E+06cm-2, ND = 1154
POOLED AGE = 66.6 ± 4.3 Ma CENTRAL AGE = 69.1 ± 5.6 Ma
A:
+2+1
0-1
-2
221 177
\
132
88
44
0.5 1.0 1.5 2.0 2.5 3.0 Wt % Chlorine
D:
300
stratigraphic age range
40
30
20
10
0 0.2 0.4 0.6 0.8 1 Weight % Chlorine
1.2 1.4 5 10 15 20 TRACKLB4GTH (microns)
20
Moore, Houseknecht, and Potter: Apatite Fission-Track Analysis of Twelve Samples
USGS Sample 99TM-564BGC763-40 APATITE IRRADIATION G820 SLIDE NUMBER 5 COUNTED BY: SJM
OF 00- 220 99TM-564B
Current grain no.
Ns Ni Na RHOs RHOi RATIO U (ppm)
a(wt%)
F.T. AGE (Ma)
345678910111415171820232627282933384143455153556162
925471323
\4152648577107231334233955880
119152114115121091415681018323171526361277219174108417214238
49709084785640806040563620606435608149602645325856100608042
2.919E+054.540E4048.828E4047.567E+041.426E+052.838E4041.192E+053.973E+047.945E4047.945E+048.513E4041.766E+051.192E+065.297E4041.490E+051.816E+052.119E+059.809E4042.270E+051.854E+056.112E+052.472E+051.142E+063.644E+061.192E+065.244E+052.516E+061.152E+063.027E+06
3.567E4052.043E4052.648E4053.973E4052.852E4053.121E4051.986E4052.384E4052.648E4053.575E4053.973E4056.621E+055.403E+062.648E+054.469E+051.362E4056.091E4053.335E+054.864E4056.886E4052.200E+064.238E4053.824E-H)66.000E+064.937E+061.716E+061.104E+074.251E+069.005E+06
0.8180.2220.3330.1900.5000.0910.6000.1670.3000.2220.2140.2670.2210.2000.3331.3330.3480.2940.4670.2690.2780.5830.2990.6070.2410.3060.2280.2710.336
2.91.62.13.22.32.51.61.92.12.93.25.343.42.13.61.14.92.73.95.517.73.430.748.239.613.888.634.172.3
0.81 '0.410.240.710.380.330.340.360.330.720.450.160.000.330.300.350.260.620.250.050.150.200.001.040.030.510.100.630.24
218.5 ± 98.460.1 ± 47.089.9 ± 46.551.5 ± 28.1134.4± 62.324.6 ± 25.7160.9 ±117.645.1 ± 34.581.0± 53.360.1 ± 47.057.9 ± 36,972.0 ± 40.659.6 ± 17.154.1 ± 41.989.9 ± 42.4
352.3 ± 269.393.8 ± 38.679.4 ± 40.4125.5± 57.572.7 ± 31.075.0 ± 26.9156.51 74.580.6 ± 19.3162.9± 18.465.2 ± 11.382.5 ± 16.561.6 ± 7.273.2 ± 11.090.7 ± 11.9
580 1821 Area of basic unit = 6.293E-07 cm-2
5.529E405
Chi Squared = 68.223 with 28 degrees of freedom P(chi squared) = 0.0 % Age Dispersion = 26.695 % Ns/Ni= 0.318 ± 0.015 Mean Ratio = 0.3631 0.045
1.736E+06 13.9 Ages calculated using a zeta of 382.4 ± 5.5 for CN5 glass Rho D = 1.420E+06cm-2; ND = 2253Rho D interpolated between top of can; Rho D= 1.397E+06cm-2, ND = 1099
bottom of can; Rho D = 1.467E+06cm-2, ND = 1154
POOLED AGE = 85.9 ± 4.6 Ma CENTRAL AGE = 86.1 ± 7.6 Ma
A:
+2+10
-1-2
352 286 221
155
90
1.0 1.5 2.0 2.5 Wt % Chlorine
3.0
C: D:
400
i. 300
200
100stratlgraphtc age range
40
30
20
10
0.2 0.4 0.6 0.8 1 1.2 1.4 Weight % Chlorine
5 10 15 20 TRACK LBJGTH (microns)
21
Moore, Houseknecht, and Potter: Apatite Fission-Track Analysis of Twelve Samples
USGS Sample 99TM-568A
GC763-41 APATITE
IRRADIATION G820 SLIDE NUMBER 6 COUNTED BY: SJM
389 1742
Area of basic unit = 6.293E-07 cm-2
3.965E405 1.776E+06 14.2
OF 00- 220
99TM-568A
Current grain no.
5678101112131718212228293031343539464752545758677375858692
Ns
3675232222'
06216
10141318
1275103
2961114228
2318
Ni
168371294
298108026204
511862115336
6364
38161152535525816
10387
Na
60282436244080648042703516702015607021100804010042304220703010050
RHOs
7.945E4043.405E+054.635E+052.207E+051.324E+051.192E+053.973E4044.966E4044.370E+05O.OOOE-fOO1.362E+059.080E4041.589E4062.270E404O.OOOE+001.059E+051.059E+052.951E+05I.362E4062.018E4069.932E+043.973E+054.767E4041.097E4063.178E+054.162E+051.112E+064.994E+054.238E+053.655E+055.721E+05
RHOi
4.238E+054.710E+064.701E+061.280E+062.648E+051.152E+06I.589E+052.483E+051.589E+069.837E+054.540E+051.816E+055.065E+064.086E+054.767E+052.119E+052.913E+051.203E+062.724E+061.011E+077.945E+041.510E+062.542E+054.351E+061.324E+061.324E+064.132E+061.317E+068.475E+051.637E+062.765E+06
RATIO
0.1880.0720.0990.1720.5000.1030.2500.2000.2750.0000.3000.5000.3140.0560.0000.5000.3640.2450.5000.2001.2500.2630.1880.2520.2400.3140.2690.3790.5000.2230.207
U (ppm)
3.437.637.610.22.19.21.32.0
12.77.93.61.5
40.53.3-3.81.72.39.6
21.880.80.6
12.12.0
34.810.610.633.010.56.8
13.122.1
a(wt%)
0.340.010.190.100.700.040.270.251.070.011.180.410.240.790.530.350.331.060.300.110.351.160.490.041.021.260.341.161.151.061.35
F.T. AGE (Ma)
50.9 ± 32.119.7± 8.3
26.8 ± 10.746.9 ± 22.7
134.9 ±116.928.2 ± 17.167.8 ± 53.654.3 ± 42.174.6 ± 18.0
0.0 ± 0.081.3± 37.9
134.9 ±116.985.0 ± 24.515.1 ± 15.60.0 ± 0.0
134.9 ±165.398.4 ± 57.566.6 + 20.7134.9± 39.154.2 ± 5.4
332.2 ± 223.071.4± 25.450.9 ± 32.168.4 ± 14.365.1 ± 29.785.1 ± 29.573.0 ± 22.1
102.6 ± 25.8134.9 ± 58.560.6 ± 14.156.2 ± 14.6
Chi Squared = 57.768 with 30 degrees of freedom P(chi squared) = 0.2 % Age Dispersion = 30.674 %
Ns/Ni= 0.223 ± 0.013 Mean Ratio = 0.288 ± 0.041
Ages calculated using a zeta of 382.4 ± 5.5 for CN5 glass Rho D = 1.426E406cm-2; ND = 2253Rho D interpolated between top of can; Rho D = I.397E+06cm-2, ND = 1099
bottom of can; Rho D = 1.467E+06cm-2, ND = 1154
POOLED AGE = 60.6 ± 3.7 Ma CENTRAL AGE = 64.2 ± 6.1 Ma
22
Moore, Houseknecht, and Potter: Apatite Fission-Track Analysis of Twelve Samples
USGS Sample 99TM-568A (continued)
OF 00- 220
GC763-41 APATITE CONTINUED 99TM-568A
+2 +1 0
-2
332 265
\
199
132
66
B:DURA NO 0
20 _ APATITE
0.5 1.0 1.5 2.0 2.5 3.0 Wt % Chlorine
C:
400
2300o> 01< g 200
100
stratigraphic age range "0.2 0.4 0.6 0.8 1 1.2 1.4
Weight % Chlorine
D:
40
30
20
10
5 10 15 20 TRACKLB4GTH (microns)
23
Moore, Houseknecht, and Potter: Apatite Fission-Track Analysis of Twelve Samples GC763-42 APATITE,RRAD,ATION0820 USGS Sa«»Ple WTM-576BSLIDE NUMBER 7 COUNTED BY: SJM
OF 00- 220 99TM-576B
Current grain no.
910111213141516192021222629303637384348535568
Ns
2061
26015112*
6046108013206310391127
Ni
58381193583104127391856377
66771610391806173
Na
4012363030206015322428302021243028281830252815
RHOs
7.945E+057.945E+054.414E+041.377E+06O.OOOE-fOO1.192E+062.648E4041.271E+062.980E+05O.OOOE+002.270E+053.178E+057.945E+056.054E+05O.OOOE+006.886E+051.135E+063.405E+052.648E+055.297E+052.479E+066.243E+052.860E+06
RHOi
2.304E+065.032E+064.855E+054.926E+062.648E+056.595E+062.648E+054.343E+061.341E+061.986E+055.108E+059.534E+054.449E+062.800E+064.635E+053.496E+064.370E+069.080E+058.828E+052.066E+061.144E+073.462E+067.733E+06
RATIO
0.3450.1580.0910.2800.0000.1810.1000.2930.2220.0000.4440.3330.1790.2160.0000.1970.2600.3750.3000.2560.2170.1800.370
U (ppm)
18.340.13.9
39.22.1
52.52.1
34.610.71.64.17.6
35.422.33.7
27.834.87.27.0
16.491.127.661.6
a(wt%)
0.030.370.060.220.000.050.000.010.030.090.020.350.010.060.000.000.170.000.230.000.180.050.51
F.T. AGE (Ma)
93.7 ± 24.443.1 ± 19.024.8 ± 26.076.1 ± 17.00.0 ± 0.0
49.3 ± 13.927.3 ± 28.779.7 ± 26.260.6 ± 27.4
0.0 ± 0.0120.6± 72.590.6 ± 42.848.7 ± 16.858.9 ± 23.0
0.0 ± 0.053.7 ± 16.470.7 ± 17.8
101.9 ± 48.881.6 ± 53.869.8 ± 24.859.1 ± 10.549.2 ± 16.2
100.5 ± 22.8
244 1018 6.214E+05 2.592E+06 20.6
Area of basic unit = 6.293E-07 cm-2
Chi Squared = 18.886 with 22 degrees of freedomP(chi squared) = 65.2%Age Dispersion = 2.250 % (did not converge)
Ns/Ni= 0.240 ± 0.017 Mean Ratio = 0217 ± 0.025
Ages calculated using a zeta of 382.4 ± 5.5 for CN5 glass RhoD= 1.432E+06cm-2; ND= 2253Rho D interpolated between top of can; RhoD= 1.397E+06cm-2, ND = 1099
bottom of can; Rho D = 1.467E+06cm-2, ND = 1154
POOLED AGE = 65.3 ± 4.9 MaCENTRAL AGE = 65.3 ± 5.0 Ma
A:
+2
+1
0-1
-2
H
a " *
a " _n n
a B a
n -» D
\ ^
1 24
120
96
72
48
C: snn
Track Age (Ma)
' ro (
> o > o
c luu i oa ;IT
0 , ._ ....
1
1
0 0.2
I. 1stratigraphic age range
i i i i i i i i
0.4 0.6 0.8 1 1.2 1.4 Weight % Chlorine
B:
20.
15
,.
D:
40
N
30
20
10
1 DURANQO APATITE
L , , , , ,0.5 1.0 1.5 2.0 2.5 3.0
Wt % Chlorine
_r
_. A.5 10 15 20
TRACK LBIGTH (microns)
24
loore, Houseknecht, and Potter: Apatite Fission-Track Analysis of Twelve Samples GC763-43 APATITE IRRADIATION G820 TTCr'C C«mnl 0 OOTlV/f ff'TCHSLIDE NUMBER 8 USCrS Sample 99TM-578B
OF 00- 220 99TM-578B
COUNTED BY: SJM
Currentgrain no.
7891112131517181920212324273440414243444649505253
Ns
003
76010085,00000
96258
3301
3130248
Ni
212
151371287812111
19013131851
16
931484441
Na
24498060100803070498035364056603625484048703650803020
RHOs
O.OOOE+00O.OOOE+005.959E+042.013E+06O.OOOE+001.986E+04O.OOOE+00O.OOOE+002.594E+059.932E+04O.OOOE+00O.OOOE+00O.OOOE+00O.OOOE+00O.OOOE+004.238E+061.271E+051.655E+053.178E+051.092E+06O.OOOE+004.414E+049.852E+055.959E+051.271E+066.356E+05
RHOi
1.324E+053.243E+043.973E+043.999E+064.767E+041.390E+055.297E+044.540E+042.821E+061.589E+054.540E+048.828E+043.973E+042.838E+042.648E+048.387E+068.263E+054.304E+057.151E+051.688E+062.270E+042.648E+052.956E+062.940E+062.331E+063.258E+06
RATIO
0.0000.0001.5000.5030.0000.1430.0000.0000.0920.6250.0000.0000.0000.0000.0000.5050.1540.3850.4440.6470.0000.1670.3330.2030.5450.195
U(ppm)
1.00.30.3
31.70.41.10.40.4
22.41.30.40.70.30.20.2
66.56.63.45.7
13.40.22.1
23.423.318.525.8
a(wt%)
0.000.000.330.610.000.330.000.000.032.800.000.000.000.000.000.080.160.420.000.660.000.410.670.690.650.64
F.T. AGE(Ma)
0.0 ± 0.00.0 ± 0.0
399.8 ±365.1136.9± 19.6
0.0 ± 0.039.2 ± 41.90.0 ± 0.00.0 ± 0.0
25.2 ± 9.3169.6 ± 96.8
0.0 ± 0.00.0 ± 0.00.0 ± 0.00.0 ± 0.00.0 ± 0.0
137.4± 17.642.2 ± 32.0
104.9 ± 55.3121. 1± 51.5175.5 ± 39.5
0.0 ± 0.045.7 ± 49.391.0± 19.055.5 ± 11.2
148.3 ± 37.853.4 ± 20.7
331 888 3.949E+05 1.059E+06 8.4
Area of basic unit = 6.293E-07 cm-2
Chi Squared = 61.272 with 25 degrees of freedom P(chi squared) = 0.0% Age Dispersion = 46.002 %
Ns/Ni = 0.373 ± 0.024 Mean Ratio = 0.248 ± 0.067
Ages calculated using a zeta of 382.4 ± 5.5 for CN5 glass RhoD= 1.438E+06cm-2; ND = 2253Rho D interpolated between top of can; Rho D = 1.397E+06cm-2, ND = 1099
bottom of can; RhoD= 1.467E+06cm-2, ND = 1154
POOLED AGE =101.7 ± 7.0 Ma CENTRAL AGE = 89,8 ± 13.6 Ma
A:
+2
+1 0
1
-2
C:
500
J 400
f 300 ^e
£ 200
8 % 100
LL.
0
(
'Hi «
-
inrD C
' .
:.\i
.4
399319 239X ' ' **
'
i
~~"
\1
1 i
stratkjraphic age range
! t t i i i i i i i i0.8 1.2 1.6 2 2.4 2.
Weight % Chlorine
15<
79
8
}
B:
20
15
10
5
D:
40
N
30
20
10
APATITE
I
I
I
I
I
I
1
HI, , , , ,0.5 1.0 1.5 2.0 2.5 3.0
Wt % Chlorine
-
rJ~
. I. .1 .5 10 15 20
TRACK LBJGTTH (microns)
25
Moore, Houseknecht, and Potter: Apatite Fission-Track Analysis of Twelve Samples GC763-44 APATITEIRRADIATION 0820 USGS Sample 99DH-52SLIDE NUMBER 9 COUNTED BY: SJM
408 1457
Area of basic unit = 6.293E-07 cm-2
7.109E405 2.539E+06 20.0
OF 00- 220 99DH-52
Current grain no.
111213141519212223242527282930313536394041467699110
Ns
5282913787210610126
2336142714313297
Ni
36901368371835
286924281467
24461125741615446069
402
Na
3570484036163530163035326028354015144245 -3824363676
RHOs
2.270E4056.356E4056.621E+043.575E4054.414E+042.980E4053.178E4054.608E+061.986E4055.297E+052.724E4054.966E4052.648E+041.135E4052.724E4059.137E+053.178E4056.810E4055.297E+05
J 7.063E+042.927E4059.270E4051368E4061.412E+062.028E+06
RHOi
1.634E+062.043E+064.304E4052.701E+061.633E+061.788E+061.589E+061.515E+078.938E4051.271E+061.271E+066.952E4051.589E4053.973E+051.090E+061.827E+061.165E+062.838E+062.800E+065.650E4056.273E4052.913E+062.648E+063.046E+068.405E+06
RATIO
0.1390.3110.1540.1320.0270.1670.2000.3040.2220.4170.2140.7140.1670.2860.2500.5000.2730.2400.1890.1250.4670.3180.5170.4640.241
U (ppm)
12.916.13.4
21.312.914.112.5
119.67.1
10.010.05.51.33.18.6
14.49.2
22.422.14.55.0
23.020.924.066.4
a(wt%)
0.090.250.060.190.000.060.770.110.750.050.000.120.050.000.000.590.010.040.100.270.620.071350.910.01
F.T. AGE (Ma)
38.2 ± 18.385.3 ± 18.642.3 ± 32.236.4 ± 13.07.5 ± 7.6
45.8 ± 28.655.0 ± 22.883.4 ± 10.461.1 ± 47.8114.0± 43.058.9 ± 26.5
194.2± 80.645.8 ± 49.578.4 ± 62.968.6 ± 31.4136.6± 35.174.9 ± 48.865.9 ± 30.052.0 ± 15.234.4 ± 25.8
127.6± 58.587.2 ± 26.9
141.1 ± 31.4126.81 27.366.3 ± 7.7
Chi Squared = 50.487 with 24 degrees of freedom P(chi squared) = 0.1 % Age Dispersion = 35.543 %
Ns/Ni= 0.280 ± 0.016 Mean Ratio = 0281 ± 0.031
Ages calculated using a zeta of 382.4 ± 5.5 for CN5 glass RhoD= 1.444E+06cm-2; ND=2253RhoD interpolated between top of can; RhoD= 1.397E+06cm-2, ND = 1099
bottom of can; Rho D = 1.467E+06cm-2, ND = 1154
POOLED AGE = 76.8 ± 4.7 Ma CENTRAL AGE = 75.9 ± 8.1 Ma
A:
+2+1
0-1-2
194 156
119
82
0.5 1.0 1.5 2.0 2.5 3.0 Wt % Chlorine
C: D:
300
§,200 <
100 stratigraphic age range 1
40
30
20
10
0.2 0.4 0.6 0.8 1 Weight % Chlorine
1.2 1.4 5 10 15 20 TRACK LBIGTH (microns)
26
Moore, Houseknecht, and Potter: Apatite Fission-Track Analysis of Twelve Samples
USGS Sample 99DH-54GC763-45 APATITE
IRRADIATION G820 SLIDE NUMBER 10 COUNTED BY: SJM
OF 00- 220
99DH-54
Currentgrain no.
3457891011121314151617182021272829
Ns
800000630000060002011
36
Area of basic unit
Ni
175431957532213
61834183
66
239
Na
8034357042603221506056406040406035356035
RHOs
1.589E+05O.OOOE+00O.OOOE+00O.OOOE+00O.OOOE+00O.OOOE+002.980E+052.270E+05O.OOOE+00O.OOOE+00O.OOOE+00O.OOOE+00O.OOOE+002.384E+05O.OOOE+00O.OOOE+00O.OOOE+009.080E+04O.OOOE+004.994E+05
6.054E+04
RHOi
3.377E+052.337E+051.816E+056.810E+047.189E+051.324E+053.476E+053.783E+059.534E+045.297E+045.675E+043.973E+047.945E+042.423E+063.178E+057.945E+041.816E+058.172E+057.945E+042.997E+06
4.019E+05
RATIO
0.4710.0000.0000.0000.0000.0000.8570.6000.0000.0000.0000.0000.0000.0980.0000.0000.0000.1110.0000.167
= 6.293E-07 cm-2 Ages calculated using a zeta o
U(ppm)
2.71.81.40.55.71.02.73.00.70.40.40.30.6
19.12.50.61.46.40.6
23.6
3.2
f 382.4 ± 5.51
a(wt%)
0.510.000.000.000.430.000.450.020.000.000.000.010.000.020.000.000.0 10.470.000.02
ror CN5 glas
FT. AGE(Ma)
129.1± 55.50.0 ± 0.00.0 ± 0.00.0 ± 0.00.0 ± 0.00.0 ± 0.0
233.3 ± 129.9164.2 ±120.0
0.0 ± 0.00.0 ± 0.00.0 ± 0.00.0 ± 0.00.0 ± 0.0
27.2 ± 11.70.0 ± 0.00.0 ± 0.00.0 ± 0.0
30.7 ± 22.90.0 ± 0.0
46.0 ± 15.0
;s
Chi Squared = 35.600 with 19 degrees of freedom P(chi squared) = 1.2 % Age Dispersion = 124.271 %
Ns/Ni= 0.151 ± 0.027 Mean Ratio = 0.115± 0.054
Rho D = 1.450E+06cm-2; ND = 2253Rho D interpolated between top of can; Rho D = 1.397E+06cm-2, ND = 1099
bottom of can; Rho D= 1.467E+06cm-2, ND= 1154
POOLED AGE = 41.6 ± 7.5 Ma CENTRAL AGE = 33.2 ± 12.9 Ma
A:
+2
233
B:DO RAN 00
20 APATITE
15
10
0.5 1.0 1.5 2.0 2.5 3.0 Wt % Chlorine
C: D: No confined tracks
300
200
100
(
(III.( >
slratigraphic age range
t i i t i i i i
0.2 0.4 0.6 0.8 1 Weight % Chlorine
1.2 1.4
27
Moore, Houseknecht, and Potter: Apatite Fission-Track Analysis of Twelve SamplesGC763-46 APATITE
IRRADIATION G820 USGS Sample 99DH-65BSLIDE NUMBER 11 COUNTED BY: SJM
OF 00-220 99DH-65B
Current grain no.
4568101112131415161920232426273031466163727374
Ns
2642312321
50196
204111515683
27397241461
Ni
351952
83433
2658810465
84211736
247
9912810
10828198
Na
38644070252525405035323030403070644035502135243048
RHOs
1.087E+061.043E+061.192E+052.724E+051.907E-K)51.271E+056.356E4041.986E+066.038E+052.724E+059.932E+052.119E+055.827E+053.973E4042.648E+053.405E+051.490E+053.178E+051.362E+058.581E+052.951E+063.178E+051.589E+067.416E+052.019E+06
RHOi
1.464E+064.842E+067.945E+041.884E+062.542E+051.907E+051.907E+051.053E+072.797E+064.540E+052.284E+062.648E+054.449E+067.945E4045.827E+051.657E+061.490E+059.534E+053.178E+053.146E+069.686E+064.540E+057.151E+061.483E+066.555E+06
RATIO
0.7430.2151.5000.1450.7500.6670.3330.1890.2160.6000.4350.8000.1310.5000.4550.2051.0000.3330.4290.2730.3050.7000.2220.5000.308
U (ppm)
11.537.90.6
14.82.01.51.5
82.521.93.6
17.92.1
34.90.64.613.01.27.52.5
24.675.93.6
56.011.651.3
a(wt%)
O.II0.420.760.061.050.380.310.050.630.760.500.620.140.541.110.202.190.910.350.570.020.780.161.220.40
F.T. AGE (Ma)
203.51 52.959.7 ± 10.3
404.5 ± 369.440.1 ± 12.4
205.41157.01 82.9 ±167.092.1 ±106.452.3 ± 8.259.8 ± 15.2
164.9 ± 85.2119.9± 32.3
2 18.9 ±146.936.3 ± 11.7
137.7 ±168.6125.3± 67.656.9 ± 16.2
272.5 ±157.592.1 ± 37.7
1 18.2 ± 81.675.5 ± 16.584.2 ± 15.6
191.91 94.761.5 1 14.0
137.7± 45.285.2 ± 12.7
409 1517 6.558E+05
Area of basic unit = 6.293E-07 cm-2
Chi Squared = 68.877 with 24 degrees of freedom P(chi squared) = 0.0% Age Dispersion = 39.843 %
Ns/Ni= 0.2701 0.015 Mean Ratio = 0.478 ± 0.063
2.432E+06 19.1
Ages calculated using a zeta of 382.4 ± 5.5 for CN5 glass Rho D = 1.455E+06cm-2; ND = 2253Rho D interpolated between top of can; Rho D = 1.397E+06cm-2, ND = 1099
bottom of can; Rho D= I.467E+06cm-2, ND= 1154
POOLED AGE = 74.6 1 4.6 Ma CENTRAL AGE = 91.2 ± 10.4 Ma
A:
+2+ 1
0-1-2
404 300 200
36
125
75
B:DO RAN 00
20 - APATITE
0.5 1.0 1.5 2.0 2.5 3.0 Wt %Chlorine
C:
500
^ 400
If 300
,? 200
g'8 100 il
0
D:
stratigraphic age range
40
30
20
10
0.4 0.8 1.2 1.6 Weight % Chlorine
2.4 5 10 15 20 TRACK LENGTH (microns)
28
Moore, Houseknecht, and Potter: Apatite Fission-Track Analysis of Twelve Samples
USGS Sample 99CP-A13
OF 00- 220
GC763-47 APATITE
IRRADIATION G820 SLIDE NUMBER 12 COUNTED BY: SJM
99CP-A13
Current grain no.
347910111417182021222326272829313233343962664448515471
Ns
362110210001070114601043347143071217412121413
Ni
1071157899
117
572428211111821819192043381611657982237567139
Na
7270563542703550304960563270402010010048351002870702856505624
RHOs
7.945E+054.767E+052.838E+059.534E+05O.OOOE+00O.OOOE+00O.OOOE+003.178E+053.708E+05O.OOOE+002.913E+051.305E+06O.OOOE+002.270E+051.589E+052.384E+054.767E+046.356E+042.317E+056.356E+054.767E+053.973E+052.724E+053.859E+052.270E+053.405E+053.814E+053.973E+058.607E+05
RHOi
2.362E+062.611E+062.213E+064.495E+063.783E+042.270E+043.178E+051.812E+061.271E+066.486E+042.172E+063.150E+065.462E+051.861E+067.151E+051.510E+063.019E+053.178E+051.424E+061.725E+062.558E+069.080E+051.294E+062.225E+061.249E+061.050E+061.780E+062.015E+062.582E+06
RATIO
0.3360.1830.1280.2120.0000.0000.0000.1750.2920.0000.1340.4140.0000.1220.2220.1580.1580.2000.1630.3680.1860.4380.2110.1730.1820.3240.2140.1970.333
U (ppm)
18.420.417.335.10.30.22.5
14.19.90.5
16.924.64.3
14.55.6
11.82.42.5
11.113.520.07.1
10.117.49.78.2
13.915.720.1
a(wt%)
0.200.690.400.000.000.000.980.400.700.000.831.120.380.410.760.410.300.330.410.500.670.870.281.020.831.670.430.781.10
F.T. AGE (Ma)
93.3 ± 18.150.8 ± 12.135.7 ± 12.059.0 ± 14.30.0 ± 0.00.0 ± 0.00.0 ± 0.0
48.8 ± 16.881.0± 34.80.0 ± 0.0
37.4 ± 12.0114.8± 20.3
0.0 ± 0.034.0 ± 11.461. 8 ± 34.244.0 ± 27.344.0 ± 27.355.6 ± 30.545.3 ± 18.5
102. 1± 32.051. 9 ± 10.4
121. 1± 55.058.6 ± 18.748.3 ± 12.750.6 ± 27.590.0 ± 30.059.6 ± 19.054.9 ± 16.192.5 ± 29.7
328 1491
Area of basic unit = 6.293E-07 cm-2
3.358E+05 1.S27E+06 11.9
Chi Squared = 44.267 with 28 degrees of freedom P(chi squared) = 2.6 % Age Dispersion = 26.368 %
Ns/Ni= 0.220 ± 0.013 Mean Ratio = 0.191 ± 0.023
Ages calculated using a zeta of 382.4 ± 5.5 for CN5 glass RhoD= 1.461E+06cm-2; ND= 2253Rho D interpolated between top of can; Rho D = 1.397E+06cm-2, ND = 1099
bottom of can; Rho D = 1.467E+06cm-2, ND = 1154
POOLED AGE = 61.2 ± 4.0 Ma CENTRAL AGE = 60.2 ± 5 J Ma
29
Moore, Houseknecht, and Potter: Apatite Fission-Track Analysis of Twelve Samples
USGS Sample 99CP-A13 (continued)
OF 00- 220
GC763-47 APATITE CONTINUED 99CP-A13
A:
+2
+10
-1 2
fc"
28
B:
0.5 1.0 1.5 2.0 2.5 3.0 Wt % Chlorine
C:
300
g.200
100
stratigraphic age range
0.4 0.8 1.2 1.6 Weight % Chlorine
2.4
D:
40
30
20
10
fl
S 10 15 20 TRACK LBJCTH (microns)
30
Moore, Houseknecht, and Potter: Apatite Fission-Track Analysis of Twelve Samples OF 00-220
REFERENCES
Fleischer, R.L., Price, P.B., and Walker, R.M., 1975, Nuclear tracks in solids, University of California Press, Berkeley.
Galbraith, R.F. 1981, On statistical models for fission-track counts. Mathematical Geology, 13, 471-488.
Galbraith, R.F. 1988, Graphical display of estimates having differing standard errors. Technometrics, 30, 271-281.
Galbraith, R.F., 1990, The radial plot: graphical assessment of spread in ages. Nuclear tracks, 17, 207-214.
Galbraith, R.F. & Laslett, G.M. 1993. Statistical methods for mixed fission track ages. Nuclear Tracks 21, 459-470.
Gleadow, A.J.W. 1981, Fission track dating methods; what are the real alternatives? Nuclear Tracks, 5, 3-14.
Green, P.P. 1981. A new look at statistics in fission track dating. Nuclear Tracks 5, 77- 86.
Green, P.P. 1985. A comparison of zeta calibration baselines in zircon, sphene and apatite. Chem. Geol. (Isot. Geol Sect), 58, 1-22.
Green, P.P., Duddy, I.R., Gleadow, A.J.W., Tingate, P.R. and Laslett, G.M. 1986. Thermal annealing of fission tracks in apatite 1. A qualitative description. Chem. Geol (Isot Geosci. Sect), 59, 237-253.
Hurford, A.J., 1986. Application of the fission track dating method to younf sediments: Principles, methodology and Examples. In: Hurford, A.J., Jager, E. and Ten Cate, J.A.M., Dating young sediments, CCOP Technical Publication 16, CCOP Technical Secretariat, Bangkok, Thailand.
Hurford, A.J. and Green, P.P. 1982. A user's guide to fission track dating calibration. Earth. Planet. Sci Lett. 59, 343-354.
Hurford, AJ. and Green, P.P. 1983. The zeta age calibration of fission track dating. Isotope Geoscience 1, 285-317.
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