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******1. Chicxulub predates the KT boundary and is not the cause for the
end-Cretaceous mass extinction <chicxpage1.html>**

*2. Chicxulub Crater *

*
2.1. PEMEX Cores: Maastrichtian Breccia? <#21>
2.2. New Evidence: Yaxcopoil-1 <#22>
2.3. Backwash and Crater Infill? <#23>
2.4. Cross-bedding? Grain size grading? <#24>
2.5. Polymict clasts? Breccia? melt rock? <#25>
2.6. Glauconite <#26>
2.7. Age of Sediments above Impact Breccia <#27>
2.8. Microfossils or Crystals? <#28>
2.9. Reworked microfossils? <#29> *

*2.9.1 Stable isotopes <#291>
2.9.2. Iridium <#292>
2.9.3. Paleomagnetic Chron 29r <#293>*

*

Summary

<#Summary>*

*3. Conclusions: Chicxulub impact predates KT by 300 kyr <chicxpage3.html>

References <chicxrefs.html>

Back to Chicxulub Debate Home Page <chicxulub.html>*

------------------------------------------------------------------------

*2. Chicxulub Crater*
In l981 a circular structure on northern Yucatan was discovered based on
gravity and magnetic anomalies that suggested an impact crater (31)
(Fig. 15). This observation lay dormant for the next 10 years. In l99l
investigation of Cores drilled by PEMEX, the Mexican state petroleum
company supported the earlier suggestion (32) and this time the
scientific community took note, leading to a 10-year hunt for evidence
in central America by a multitude of scientists (46).

<fig15.jpg>

Figure 15. Magnetic and gravity anomaly map of the circular subsurface
structure at Chicxulub (Sharpton, LPI). .

Click on the figure for a larger view.

*
2.1. PEMEX Cores: Maastrichtian Breccia?*
PEMEX cores, and particularly the stratigraphic position of the breccia
and the age of the limestones overlying it, were controversial from the
beginning. At issue was a report by PEMEX investigators of the l970’s
(Meyerhoff and others (33) and Lopez Ramos (34, 35) who reported
limestones with diverse planktic foraminiferal assemblages of upper
Maastrichtian age overlying the breccia in wells C1 and Y6 (Fig. 15). If
true, then the impact breccia below it could not be of KT age.

Ward et al. (36) re-examined the stratigraphy, paleontology and
sedimentology of PEMEX cores Yucatan core Y1, Y2, Y4, Y5A, and Y6, no
samples could be obtained from wells Sacapuc 1 (S1), Chicxulub 1 (C1)
and Ticul 1 (T1) (Fig. 15), and they relied on e-logs and published
lithologic and paleontologic descriptions for these wells. For all wells
resistivity-spontaneous potential logs were available and these were
examined and correlated (Fig. 16).

								<fig16.jpg> 	Figure 16. Correlation of Yucatan wells modified
from Ward et al. (32). Note that the there is e-log and planktic
foraminiferal evidence for upper Maastrichtian marls or limestones
overlying the impact breccia at wells T1, Yax-1 (new core), Y6 and C1.

Note also that sediments underlying the breccia are normally stratified
in all but wells C1 and Y6 near the center of the impact crater.

Click on the figure for a larger view. 								

Core recovery for the KT boundary was generally poor and no samples
could be obtained from well C1. One sample obtained from A. Hildebrand
for well Y6 (N12) at about 1000-1003 m yielded a Paleocene (zone P3)
age. Hildebrand et al (32, writtine comm.. 2003) argued that this
Paleocene age invalidates the late Maastrichtian age assigned by earlier
studies. However, sample Y6 N12 is about 40 to 50 m above the breccia
and no conclusion can be reached regarding the age of the breccia. For
example, in the new well Yaxcopoil-1, Paleocene zone P3 faunas are
present already at 70cm above the impact breccia. The amount of
Maastrichtian or early Paleocene sediments present above the breccia is
dependent on erosion events and the paleotopography.

Because of the lack of samples for examination by Ward and others (36)
of the critical interval, no precise age could be independently
determined for the sediments directly overlying the breccia. However,
e-log correlations indicate that “the top of the breccia could be as
high as 938m, the lowest depth at which presumably undisturbed marls and
limestones can be correlated on electric log characteristics with
equivalent beds in S1.” Ward et al. concluded that “There is some
evidence that the breccia unit is overlain by about 18 m of uppermost
Maastrichtian marl, suggesting an impact before the Cretaceous-Tertiary
boundary.”
*
2.2. New Evidence: Yaxcopoil-1*
In 2000-2001 the International Continental Drillling Program (ICDP)
supported the drilling of a new core by the Chicxulub Scientific
Drilling Program (CSDP). One of the major objectives of this project was
to settle the controversial issue of the age of the impact breccia and
hence the age of the Chicxulub impact (37). A site on the Hacienda
Yaxcopoil was chosen. The site was believed to be in the center of the
crater and drilling was expected to recover the impact melt sheet and
thick breccia deposits (Fig. 17). This was not the case. No melt sheet
was recovered and the breccia was only 100 m thick, significantly less
than the 300-600 m recovered by PEMEX. This suggests that drilling
occurred near the crater rim on uplifted fault blocks (Fig. 18).

<fig17.jpg>

Figure 17. Model of the Chicxulub impact crater, showing the central
uplift, impact melt sheet and breccias. The new core Yax-1 was expected
to penetrate the melt sheet and several hundred meters of breccia.
Instead, no melt sheet was recovered and the breccia is only a100m
thick. This suggests that drilling occurred near the crater rim on
uplifted fault blocks.

Click on the figure for a larger view.

<fig18.jpg>

Figure 18. Thickness of breccia units recovered by drill cores on Yucatan.

Click on the figure for a larger view.

Yaxcopoil-1 drilled to a depth of 1511m within the Chicxulub crater. An
organic-rich marly limestone near the base of the hole (1495m to 1452m)
was deposited in an open marine shelf environment during the latest
Cenomanian (top of Rotalipora cushmani zone). The overlying sequence
consists of limestones, dolomites and anhydrites (1495m to 894m) and
indicates deposition in various carbonate platform environments (e.g.,
sabkhas, lagoons). A 100m thick suevite breccia (894-794m) identifies
the Chicxulub impact event. Above the suevite breccia are dolomitic,
micritic limestone and limestones. The KT boundary is 50 cm above the
suevite breccia (Figs. 19, 20).

<fig19.jpg>

Figure 19. Core Yaxcopoil-1, Chicxulub, showing the uppermost part of
the suevite breccia and the lower 20 cm of the overlying dolomitized,
laminated micritic breccia. Note that the upper 15m of the suevite
breccia are reworked and current bedded. Melt glass and spherules are
common in this interval.

Click on the figure for a larger view.

<fig20.jpg>

Figure 20. Core Yaxcopoil-1, Chicxulub, showing the green clay of the KT
boundary (30cm up from the core base) and early Tertiary limestones.

Click on the figure for a larger view.

*
2.3. Backwash and Crater Infill?*
The 50 cm thick laminated, partially dolomitized, micritic limestone
that unconformably overlies the suevite breccia and underlies the KT
boundary holds the key to determining the age of the Chicxulub impact
and the nature of the post-impact paleoenvironment (Fig. 21). In order
to have a common origin for the suevite breccia and the KT boundary,
this 50 cm layer must be interpreted as part of the impact event, such
as backwash and crater infill, as commonly argued (32, 38a,b)
Hildebrand, written comm. 2003). In support of this interpretation, it
is claimed that this 50cm interval shows high-energy activity in the
form of cross bedding and grain size grading, abundant impact melt rock
now altered to green clay layers and quartz minerals.
	  	  	  	  	<Slide9.jpg> 	

Figure 21. Lithology of the critical 50cm interval between the impact
breccia and the KT bondary in well Yaxcopoil-1. If the impact breccia is
KT age, then this 50 cm interval of sediments must be interpreted as
backwash and crater infill deposited over a geologically instantaneous
time span. Sediment and microfossil analyses indicate deposition
occurred during the last 300 ky of the Maastrichtian in variable but low
energy environments.

Click on the figure for a larger view.

Backwash and crater infill is expected to erode, transport and redeposit
material from the surrounding crater walls via slumps or gravity flows
due to earthquakes or unstable topography, and by currents. Hildebrand
argues that Gulf of Mexico waters rushed in through a 100km wide and 1km
deep trough, sliced off by the impact in the northern part of the
crater, transporting a mix of reworked sediments and faunas and
depositing them in the crater (written comm.. 2003). These scenarios can
be evaluated based on the sediments overlying the Chicxulub breccia. To
validate the backwash and crater infill scenario the sediments must contain:

1. Sedimentary structures indicative of high-energy currents (e.g.
cross-bedding, flaser bedding, grain size grading.

2. Highly variable lithoclasts from the diverse underlying strata,
such as shallow water limestones, gypsum, dolomite, anhydrite, plus
breccia clasts.

3. A significant amount of melt rock either as glass fragments or
glass altered to Cheto smectite.

4. Reworked microfossil and macrofossil faunas from the underlying
sediments, such as shallow water benthic foraminifera and
invertebrates that are common in the lagoonal to subtidal Cretaceous
environments of the Yucatan platform, though no planktic foraminifera.

5. Reworked fauna must show evidence of diverse ages reflecting the
deep erosion and disturbance of underlying sediments.

In contrast, normal pelagic sedimentation is indicated if the sediments
show:

1. No grain size grading or other high-energy current bedding,

2. Lack clasts of breccia, melt rock, or other lithologies,

3. Lack reworked faunas and burrowing organisms,

4. Contain evidence of in situ accumulated sediments such as galuconite

5. Contain microfossil assemblages characteristic of a narrow age
interval.

Our sediment analyses have addressed these issues based on thin section
investigations, XRD, ESEM, isoluble residues, and microfossils. We
discuss the results below.

*2.4. Cross-bedding? Grain size grading?*
The sediments of the 50 cm interval predominantly consist of laminated
micritic limestone with patches or microlayers of dolomite. The micritic
limestone is finely crystalline, whereas the dolomite crystals are large
and angular. At first sight this may give the impression of grain size
grading. However, dolomite formed by diagenetic replacement of the
precursor (micritic) limestone with the laminated texture still visible.
The micritic limestone indicates deposition in quiet water conditions.
			<fig22.jpg> 	

Figure 22. Limestone lithologies from Yax-1. Numbrs refer to samples
indicated in Figure 21. 12. Laminated microlayers in micritic limestone,
16, laminated microlayers micritic limestone enhanced by partial
dolomitization of some layers, 18. laminated microlayers micritic
limestone enhanced by early stage dolomitization, 21. Dolostone,
advanced diagenetic alteration of the original micritic limestone and
replacement by angular dolomite crystals.

Click on the figure for a larger view.

Core Yax-1 shows three <1 cm thick layers of oblique bedding within an 8
cm thick interval between 794.45 and 794.53 m that has been referred to
as cross-bedding (Fig. 21). Cross-bedding must have grain size changes
of at least medium to fine grained sand. We found no grain size changes
and samples dissolved in acid show almost no insoluble residues and no
quartz grains. We could not confirm Smit’s claim of common sand grains
with dolomite overgrowth (38b). If such sand grains were present, they
should be in the insoluble residues. The apparent grain size change in
these sediments is diagenetic due to dolomitization (see Fig. 22).

Grain size change is also characteristic of flaser bedding. Based on
visual examination we thought there was flaser bedding, though insoluble
residues revealed only some glauconite or glauconite coated microclasts.
Burrowing structures account for the apparent mottled character of these
intervals.

Based on our analyses we could not confirm the presence of
cross-bedding, flaser-bedding or grain size grading. Diagenetic growth
of dolomite crystals, burrowing organism and glauconite formation appear
to account for the features identied as evidence of high-energy current
bedding.

*2.5. Polymict clasts? Breccia? melt rock?*
By visual core examination, we originally identified several very thin
(<0.5 cm) microconglomerate layers as possibly supporting reworking and
redeposition from the breccia. Closer examination revealed five thin
green clayey microclast layers interbedded with the laminated micritic
limestone (794.43, 794.34-35, 794.24, 794.19, 794.11)(Fig. 21).
Insoluble residues revealed these microclasts to be of glauconitic
origin or have in situ glauconite coating (see below). We observed only
very rare clasts and very rare glass shards (Fig. 23). These
insignificant amounts argue against backwash and crater infill from
reworked and transported material.

							<fig23.jpg> 	

Figure 23a. Impact glass in Sample 10 below KT boundary.

Click on the figure for a larger view.

							Fig. 23b. Yaxcopoil-1, sample 8, KT green clay layer is a mature
glauconite. Sample 10 is a rare glass shard from the bioturbated
interval below the KT boundary.

Click on the figure for a larger view.

*2.6. Glauconite*
The five green clay and glauconite layers at the KT boundary and below
it have been interpreted by Smit and others (38a,b) as evidence of
abundant altered impact glass.
Impact glass alters to a characteristic, almost pure Cheto smectite (16,
39). XRD and ESEM analyses indicate that Cheto smectite is present in
the impact breccia. However, the green clay at the KT boundary, or in
the other four intervals, is of glauconitic origin and represents a
mature glauconite (40) (Fig. 24).

* <fig24.gif>*

Figure 24. Evidence for pre-K-T age of the Chicxulub Crater. New
evidence from the Chicxulub core Yaxcopoil-1, which was drilled on the
flank of the crater, reveals a pre-K-T age for this impact event. The
evidence is based on several independent proxies, including
sedimentology, mineralogy, magnetostratigraphy and micropaleontology.
The age determination is based on sediments between the impact breccia
and the K-T boundary, which contains planktic foraminifera
characteristic of the last 300,000 years of the Cretaceous and
paleomagnetic chron 29R which spans the last 500,000 years of the
Cretaceous and first 270,000 years of the early Tertiary. These
sediments were deposited in a normal marine environment where laminated
limestones alternated with deposition of five glauconite layers.   The
top glauconite layer marks the K-T boundary and a hiatus. Glauconite
forms over tens of thousands of years in slightly agitated bottom
waters. The sediments also contain fossil burrows, which indicate that
invertebrates colonized the ocean floor during deposition. Together this
evidence rules out chaotic and rapid deposition via tsunami or backwash
after the impact.

Click on the figure for a larger view.

Glauconite forms at the sediment-water interface in environments with
very slow detrital accumulation as a result of sediment winnowing by
gentle bottom currents and clast generation. The five green layers
therefore indicate long pauses in the overall quiet depositional
environment with slightly more active, though still minor current
activity and small-scale transport. Glauconite layers are
characteristically burrowed and the five thin layers in the 50cm thick
interval above the impact breccia are no exception. Although burrowing
(Thalassinoides, Spreiten) is strongest in the 8 cm below the KT
boundary glauconite layer, each of the four lower glauconite layers is
also burrowed.

The five layers of glauconite formation thus effectively rule out a
scenario of rapid deposition, high-energy currents, backwash and crater
infill.

*2.7. Age of Sediments above Impact Breccia*
The depositional age of the 50 cm thick laminated micritic limestones
between the top of the suevite breccia and the KT boundary can be
determined from the presence of planktic foraminifera. This critical
interval contains diverse planktic foraminiferal assemblages
characteristic of zone CF1, which spans the last 300 kyr of the
Maastrichtian (Fig. 25a). These assemblages include /Globotruncana
stuarti, G. insignis, G. arca, G. falsocalcarata, Abathomphalus
mayaroensis, Rosita contusa, R. petaloidea, R. walfishensis,
Rugoglobigerina rugosa, R. macrocephala, Plummerita hantkeninoides,
Globotruncanella petaloidea, / /Heterohelix, Hedbergella/ sp. and
/Globigerinelloides aspera/ (Fig. 25b). Small benthic foraminifera are
also present (mostly buliminellids), but there are no reworked shallow
water benthic foraminifera from below the breccia. No planktic
foraminifera lived within the lagoonal to subtidal environment of the
pre-impact Yucatan platform.

These foraminiferal assemblages indicate deposition occurred after the
impact event and prior to the KT boundary mass extinction, sometime
during the last 300 kyr of the Maastrichtian, similar to the age of
spherule deposition in NE Mexico.

<fig25a.gif>

								  	Figure 25a. Planktic foraminiferal ranges in the Chicxulub
core Yax-1 show a typical late Maastrichtian assemblage, and carbon
isotopes show the characteristic high late Maastrichtian values for the
interval between the impact breccia and the K-T boundary. The K- T
boundary is marked by a drop in the carbon isotopes and the first
appearance of new Tertiary species. This same pattern exhibited in the
Chicxulub core Yax-1 has been observed from hundreds of sections
worldwide and testifies that this is not a random coincidence of
post-impact disturbance. 											

* <fig25.jpg>*

Figure 25b. Planktic foraminifera from the early Danian zone Pla and
zone CF1, which spans the last 300 kyr of the late Maastrichtian at
Yax-1, Chicxulub. Zone Pla: 1./ Woodringina hornerstownensis/, 2.
/Parvularugoglobigerina eugubina,/ 3. /Parasubbotina pseudobulloides/,
4. /Morozovella inconstans/ (sample 4, zone Plc). 5. /Plummerita
hantkeninoides/ (sample 20); 6. /Rugoglobigerina macrocephala/ (sample
9); 7. /R. rugosa/ (sample 12); 8. /R. hexacameratea/ (sample 10); 9 &
10./ Globotruncana insignis/ (sample 20); 11. /Rosita contusa /(sample 9).

Click on the figure for a larger view.

*2.8. Microfossils or Crystals?*
The images in Figure 25 are demonstrably those of planktic foraminiferal
species. This is evident when the thin section images are compared with
3D images of the same species from well-preserved specimens at El Kef,
Tunisia (Figure 26a). It has been suggested that the microfossils
identified by GK are just crystals (Smit, in (41) and written comm..
Sept. 26, 2003, CCNET). Smit states that “neither the Zaragoza group nor
I were able to find any determinable foraminiferal remains in any of the
samples. Instead, we found in thin sections exclusively rhomb-like
idiomorphic dolomite overgrowths of sand grains. The rhombs resemble in
size and thickness somewhat the testwalls of foraminifers.” Smit
illustrated this with the micrograph show in Figure 26b.

	  	  	  	  	  	  	  	  	  	<fig26a.gif> 	

Figure 26a. Micrographs of Late Maastrichtian planktic foraminifera from
the Chicxulub Yax-1 core between the impact breccia and the K/T boundary
and comparison with the pristine 3D images of the same species from the
El Kef section of Tunisia. (1. Globotruncana insignis, 2.
Rugoglobigerina rugosa, 3. R. macrocephala, 4. Plummerita
hantkeninoides). Note that the Yax-1 specimens show the same number of
chambers, chamber arrangement and coil, size and morphology as the
pristine species. This demonstrates that these images are foraminiferal
species, rather than dolomite rhombs as claimed by Smit.

Click on the figure for a larger view.

Micritic limestones are notorious for poor foraminiferal preservation
and no nannofossils are preserved. Micrite recrystallizes the limestone
and the calcite of the foram shells. Frequently all that is left is the
knobby structure of the shell rim or keel and the white color of the
original test calcite showing the morphology and test chambers of the
species (Fig. 26). At very high magnification the foraminiferal shapes
dissolves into the surrounding crystalline matrix. There is only a
limited range of magnification in which the shapes can be viewed and
illustrated. This limits relatively clear illustrations to the largest
species (globotruncanids and some rugoglobigerinids, with smaller
species fuzzy at the magnification required for illustration. In
sediments that are also partially dolomitized, preservation of
foraminiferal species is even more difficult since dolomite rhombs are
rather large (as shown in Figure 22, dolostone sample 21) and consume
larger parts of the test shells. But they never resemble testwalls of
foraminifers. This claim by Smit suggests that he and Arz searched for
the foraminifera in dolomitic intervals, where indeed there are no
recognizable foraminifera preserved.

However, the argument by Smit and Arz that no Maastrichtian foraminifera
are preserved in these micritic limestones is now mute because Arz and
others confirmed their presence as published in the July 2004 volume of
Meteoritics and Planetary Science (see Arz et al., MAPS 39(7), 1099-1111
(2004).

	  	  	  	  	  	<fig26b.gif> 	

Figure 26b. Smit's illustration of a dolomite rhomb that he thinks
resembles a foraminifera.

Click on the figure for a larger view.

*2.9. Reworked microfossils?*
Could these microfossils be reworked? Smit (38b) claims that “even if
the foraminiferal fossils were missed by the Zaragoza (Arz) and
Amsterdam (Smit) groups, they would not permit any conclusion about the
age of the crater” because “cross- and parallel beds tell any
sedimentologist that such sediments are deposited by currents and waves
and that all grains in those beds, including foraminiferal shells, are
transported from another source.”

It is important to remember here that Smit’s “cross-beds” refer to three
< 1cm thick micritic limestone layers with oblique bedding,which contain
no sand grains, or size grading, except for (diagenetic) dolomite
crystals (see section 2.4). Similarly, the “parallel beds” are
millimeter thin micritic limestone laminations (see Fig. 21). Moreover,
there are five thin glauconitic layers interbedded within this 50cm
thick interval (sec. 2.6). As demonstrated above (sections 2.3 to 2.6),
micritic limestone and finely laminated limestones, such as in Yax 1
between the KT and the impact breccia, form in quiet water environments
and glauconite forms in slightly agitated waters with little or no
sediment accumulation. Neither of these sediments lend any credence to
an interpretation of significant transport and reworking, much less “all
grains” transported from “the crater rim or the direct surroundings of
the crater”(38b).

Apart from the sedimentological evidence for quiet pelagic
sedimentation, there is also no evidence for significant reworking in
the form of transported clasts from the breccia or of microfossils
within them (sec. 2.5), or from the sediment below. Moreover, the
shallow lagoonal to subtidal platform environment that prevailed prior
to the Chicxulub impact did not support planktic foraminifera.
Therefore, the late Maastrichtian assemblages would have had to be
transported a long distance by strong backwash or tsunami waves from the
open marine Gulf of Mexico. But there is no evidence for such high
energy deposition. Moreover, such backwash and tsunami waves would have
ripped up and transported sediments, clasts, and microfossils from
various older Cretaceous ages. But there is no evidence for such
reworking (sec. 2.5). The planktic foraminiferal assemblages are
characteristic of the narrow interval of zone CF1, which spans the last
300 kyr of the late Maastrichtian.

We conclude that the zone CF1 assemblages that characterize the 50 cm
interval between the KT boundary and suevite breccia were deposited
after the Chicxulub impact in a normal pelagic environment that was deep
enough to support planktic foraminifera.

*2.9.1 Stable isotopes*
Carbon Isotopes (42) of bulk rock samples in the 50 cm thick micritic
limestone above the impact breccia reveal consistently high d13C values
characteristic of the late Maastrichtian, followed by the signature 2‰
negative excursion at the K-T boundary (Fig. 27). Only sample 21 shows
anomalously low d13C (0.76‰ and 1.7‰) and d18O (- 4.33‰ and -1.24‰)
values as a result of diagenesis in this completely dolomitized
limestone (see Fig. 22).

These data reveal the carbon and oxygen isotope values in the micritic
limestone to be within the range of late Maastrichtian sediments,
indicating the absence of any significant diagenetic overprint. The drop
of about 2‰ in _13C at the top of the glauconitic layer is in a typical
range observed for the K/T transition worldwide. The relative constant
C- and O-isotope values argue against chaotic reworking and transport of
this sequence. In addition, trace element concentrations are nearly
constant through this section (42), and Ir concentrations are steadily
increasing up to the K/T boundary. These features also argue against
major reworking of this sedimentary sequence.

By itself, the stable isotope data does not conclusively show that these
sediments are not reworked, because sediment settling from the water
column after the impact event could yield similar Cretaceous isotope
signals. However, together with the Ir data, other trace elements,
absence of reworking,or high-energy current transport in sediments, and
presence of glauconite layers all support normal pelagic sedimentation.
	  	  	  	<fig27.jpg> <Slide10.jpg> 	

Figure 27. Stable isotopes, Ir concentrations and paleomagnetic
stratigraphy in the micritic limestone above the Chicxulub suevite
breccia. Note the late Maastrichtian carbon isotope signal and
characteristic negative excursion that marks the KT transition in low
and middle latitudes. Ir concentrations are low and probably within
background values. The absence of an Ir anomaly at the KT boundary is
due to a major hiatus.

Click on the figure for a larger view.

*2.9.2. Iridium *
Iridium concentrations at Yax-1 are minor (0.06-0.08 ng/g) in the first
20 cm of the micritic limestone overlying the suevitic breccia and
increase only slightly to reach maximum values of 0.3 ng/g in the
glauconitic layer at 794.08 - 794.14m that marks the KT boundary (Fig.
27). Two centimeters above Ir concentrations return to values of 0.06 -
0.08 ng/g. The absence of an Ir anomaly at the KT boundary is due to a
hiatus that spans the lower Danian (lower part of Pla) and probably the
uppermost Maastrichtian interval.

*2.9.3. Paleomagnetic Chron 29r*
Paleomagnetic analysis (43) of the 56 cm micritic limestone above the
impact breccia reveal reversed polarity of C29r, which spans
approximately the last 500 kyr of the Maastrichtian and first 270 kyr of
the Tertiary (Fig. 27). The fact that only about 6 cm of the early
Tertiary C29r interval is present confirms the hiatus identified by
planktic foraminifera (44). Thus, paleomagnetic data are consistent with
the planktic foraminiferal data that indicate zone CF1, which spans the
last 300 kyr of the Maastrichtian, the stable isotope data, and the
evidence of normal pelagic sedimentation.

*Summary*
The Chicxulub impact predates the K-T boundary mass extinction by about
300,000 years based on the new evidence from sediments, geochemistry,
paleomagnetism and microfossils in the Chicxulub crater core Yax-1. This
supports the earlier evidence from northeastern Mexico where Chicxulub
impact glass spherules (microtektites) are interbedded in late
Maastrichtian sediments that predate the K-T boundary by 300,000 years.
The Chicxulub impact coincided with a major climate warming as a result
of Deccan Trap volcanism, but caused no species extinctions (Figure 28).
The mass extinction at the K-T boundary coincided with a major iridium
anomaly which indicates a second, probably much larger, impact for which
no crater has been found to date. This second K-T boundary impact also
coincided with a major increase in Deccan volcanism. The killing
mechanism of the K-T mass extinction seems to be the result of the
unfortunate coincidence of major volcanism and a large impact, rather
than a single large impact alone.

<fig28.gif>

Figure 28. Multiple impacts and massive volcanism are the twin causes of
the K-T boundary mass extinction. The Chicxulub impact occurred 300,000
years before the K-T and coincident with a major Deccan volcanism
induced greenhouse warming, but caused no species extinctions. The
ultimate cause for the K-T mass extinction is the unfortunate
coincidence of major volcanism and a large impact.

Click on the figure for a larger view.

<Slide11.jpg>

Figure 28A. The results of  the Chicxulub crater core were published in
/The Proceedings of the National Academy of Sciences/ in March 2004.

Click on the figure for a larger view.

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**1. Chicxulub predates the KT boundary <chicxpage1.html>**
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