Journal of Foraminiferal Research, v. 38, no. 2, p. 162-182, April 2008 
CHRONOSTRATIGRAPHIC FRAMEWORK FOR UPPER CAMPANIAN-MAASTRICHTIAN 
SEDIMENTS ON THE BLAKE NOSE (SUBTROPICAL NORTH ATLANTIC) 
BRIAN T. HUBER'**, KENNETH G. MACLEOD^ AND NATALIYA A. TUR' 
ABSTRACT 
A new chronostratigraphic framework is presented for 
upper Campanian-Maastrichtian pelagic sediments cored at 
DSDP/ODP Sites 390A/1049, 1050, and 1052, which were 
drilled across a 1300-m depth transect on the Blake Nose 
(subtropical western Atlantic Ocean). The planktonic fora- 
miniferal zonation is based on standard global biozones for 
this interval, but rare and sporadic occurrence of two zonal 
biomarkers, Ganssevina ganssevi and Globotruncana aegyp- 
tiaca, precludes reliable identification of the nominate zones 
for those species. The Pseudoguembelina palpebva Partial- 
range Zone is defined as a means of subdividing this upper 
Campanian biostratigraphic interval. Planktonic foraminif- 
eral, calcareous nannofossil and paleomagnetic datums are 
integrated to construct reliable age-depth curves for each of 
the Blake Nose drill sites. These age models are largely 
confirmed by Sr-isotopic data and suggest significant 
unconformities at various positions within the sections. 
Compilation of stable isotope datasets for this time interval 
from the Blake Nose sites reveals no significant shifts in 5'^0 
and 6"C at the time of the inoceramid bivalve extinction (now 
dated as 68.5-68.7 Ma in the Blake Nose sections) and no 
correlation with proposed Campanian-Maastrichtian glacial 
intervals. However, benthic warming associated with Deccan 
volcanism during the late Maastrichtian is supported. 
INTRODUCTION 
Late Campanian through Maastrichtian events have been 
the topic of a number of paleontological debates that 
cannot be resolved without a reliable regional and global 
chronostratigraphic framework. Of principle interest are 
investigations of (1) the likelihood that ice sheet growth 
caused positive shifts in the marine oxygen isotope record 
and widespread unconformities in continental margin 
stratigraphic sequences during the mid-Campanian, late 
Campanian and early Maastrichtian (Miller and others, 
1999, 2005; Jarvis and others, 2002; Huber and others, 
2002); (2) whether global warming (inferred from oxygen 
isotopes) and poleward migration of thermophilic plank- 
tonic foraminifera during the latest Maastrichtian were 
synchronous with the onset of Deccan Trap volcanism, as 
has been reported by various authors (e.g., Huber, 1990; 
Huber and Watkins, 1992; Barrera and Savin, 1999; Olsson 
and others, 2001); (3) the nature of the "mid-Maastrichtian 
Event," for which global extinction among deep-sea 
inoceramid bivalves has been related to a change in deep- 
' Department of Paleobiology, MRC-121, Smithsonian Museum of 
Natural History, Washington, DC 20013-7012 
"Department of Geological Sciences, University of Missouri- 
Columbia, Columbia, MO 65211 
^All-Russian Geological Institute (VSEGEI), Sredny pr., 74, St.- 
Petersburg, 199106 Russia 
^ Correspondence author. E-mail: huberb@si.edu 
ocean circulation, as evidenced by a negative excursion in 
global deep-sea benthic carbon isotope values and a 
positive shift in oxygen isotope values (MacLeod, 1994; 
MacLeod and Huber, 1996; MacLeod and others, 2000; 
Frank and Arthur, 1999; Frank and others, 2005); and (4) 
extinction patterns of planktonic foraminifera below and 
across the Cretaceous-Paleogene mass extinction event 
(e.g., Keller, 1988, 2004; Keller and others, 1993; Abramo- 
vich and others, 1998; Norris and others, 1998; Arenillas 
and others, 2000; Arz and others, 2000, 2001; Huber and 
others, 2002; Molina and others, 2005; MacLeod and 
others, 2007). 
Late Campanian-Maastrichtian sediments drilled on the 
Blake Nose, in the subtropical North Atlantic Ocean 
(Fig. 1), have figured prominently in these debates because 
of the unusually good preservation of calcareous microfos- 
sils and relatively complete composite core recovery for a 
region and range of depths otherwise lacking good 
Campanian-Maastrichtian data. Deep Sea Drilling Project 
(DSDP) Hole 390A (Leg 44; Benson and others, 1978) and 
Ocean Drilling Program (ODP) Sites 1049, 1050 and 1052 
(Leg 171B; Norris and others, 1999) were drilled along a 50- 
km depth transect from 2700 to 1300 m water depth at the 
edge of the Blake Nose escarpment (Fig. 1). Paleolatitude 
of the sites is estimated as 25?N (Ogg and Bardot, 2001). A 
seismic reflection profile across this transect reveals a 
shallowly buried Aptian-Eocene sequence of pelagic ooze 
and chalk that gently slopes and gradually thins eastward to 
the Blake Escarpment (Norris and others, 1998, p. 353, 
Fig. 3). The Campanian-Maastrichtian interval is thickest 
at Site 1052, which recovered 172 m of hemipelagic chalk, 
and is thinnest at Site 1049 and Hole 390A, which recovered 
about 20 m of pelagic chalk. Although slump features are 
apparent at several levels of all three sites (Norris and 
others, 1998), no evidence for stratigraphic repetition has 
been presented (MacLeod and others, 2003). 
Detailed investigations of faunal and stable isotopic 
investigations associated with the "mid-Maastrichtian 
Event" (sensu Frank and others, 2005) have been under- 
taken on samples from Hole 390A (MacLeod and others, 
2000; Friedrich and others, 2004), and the site was re- 
sampled as Site 1049 of ODP Leg 171B. Isotopic trends and 
their relationship to Maastrichtian North Atlantic paleo- 
ceanography and foraminiferal paleobiology were exam- 
ined at Sites 1050 and 1052 (MacLeod and others, 2005; 
Isaza-Londono and others, 2006). Campanian-Maastrich- 
tian studies of the Leg 171B Blake Nose drill sites also 
include examination of relative abundance changes among 
planktonic foraminifera and calcareous nannofossils below 
and across the Cretaceous-Paleogene boundary (Norris and 
others, 1999; Huber and others, 2002; Self-Trail, 2001, 
2002; Watkins and Self-Trail, 2005); strontium isotope 
evidence for slope failure, sediment reworking and ocean 
chemistry related to the boundary (MacLeod and others. 
162 
BLAKE NOSE CHRONOSTRATIGRAPHY 163 
77?00 W 76?30 W 76?00W 
FIGURE 1. Location of DSDP Hole 390A and ODP Sites 1049, 
1050 and 1052 on the Blake Nose and relative to the southeast coast of 
North America (inset). Depth in meters. 
2001a; MacLeod and others, 2003); long- and short-term 
variations in the oxygen and carbon isotopic record 
(MacLeod and others, 2000, 2005; MacLeod and Huber, 
2001; Wilf and others, 2003), and the effects of Milanko- 
vitch forcing on sedimentation and foraminiferal distribu- 
tions during the mid-Maastrichtian (MacLeod and others, 
2001b). Collectively, these studies span a range of 
important paleoceanographic and paleoclimatological top- 
ics, but they have used a variety of age models that 
complicate integration of the results and comparison of 
Blake Nose patterns to events documented in other regions. 
The objective of this study is to develop age-depth models 
for the Campanian-Maastrichtian intervals at each of the 
Blake Nose sites using the best available planktonic 
foraminiferal, calcareous nannofossil and paleomagnetic 
datum events calibrated with a current geological time scale 
(Gradstein and others, 2004). Better age models enable a 
more reliable calculation of sedimentation rates, determi- 
nation of the distribution and duration of hiatuses, and 
estimation of ages for first and last occurrence datums of 
previously uncalibrated planktonic foraminiferal and cal- 
careous nannofossil species. Most importantly, establish- 
ment of the age-depth relationships for each of the Blake 
Nose sites enables examination of the degree to which biotic 
and paleoceanographic events observed on the Blake Nose 
are synchronous across the depth transect and with events 
observed at other localities worldwide. 
MATERIAL AND METHODS 
Planktonic foraminifera are abundant, and the assem- 
blages are diverse and moderately to very well preserved at 
each of the Blake Nose sites (Norris and others, 1998). 
Sampling resolution from Leg 171B sites varies depending 
on proximity to bio- and lithostratigraphic boundaries and 
thickness of the Campanian-Maastrichtian interval. A total 
of 40 samples between 132.25 and 112.97 meters below 
seafloor (mbsf) were studied from Hole 1049C with an 
average sample spacing of less than 0.5 m; 53 samples 
between 484.56 and 405.92 mbsf were studied from Hole 
1050C with an average sample spacing of 1.5 m; and 85 
samples between 475.45 and 302.17 mbsf were studied from 
Hole 1052E with an average sample spacing of 2.0 m. For 
Hole 390A samples from the study of MacLeod and others 
(2000), which generally had 0.75-m sample spacing, were 
analyzed and supplemented with additional samples to 
improve biostratigraphic resolution and to identify datum 
events that were not recognized in the MacLeod and others 
(2000) study. 
Most nannofossil datums reported are from published 
sources. The ages and depths used are cited in Tables 1-5. 
Smear slides were prepared during the present study for 
select Maastrichtian samples from DSDP Hole 390A and 
ODP Hole 1049C in an effort to determine the stratigraphic 
distribution of several calcareous nannofossil zonal marker 
taxa that are included in Tables 2 and 3. 
Paleomagnetic chron assignments for the Leg 17IB drill 
sites are based on the magnetic polarity data of Ogg and 
Bardot (2001), which include shipboard measurement of 
natural remnant magnetization of continuous half-core 
sections yielding a sample resolution of about 5 cm. These 
data were supplemented by shore-based progressive de- 
magnetization of about two discrete samples per core- 
section (about 0.75 m apart). As noted in Ogg and Bardot 
(2001), many of the polarity chron boundaries in the 
Campanian-Maastrichtian cores were indeterminate be- 
cause of stratigraphic discontinuities, poor paleomagnetic 
characteristics and synsedimentary slumping and/or dril- 
ling-induced disruption. As a result, only chron boundaries 
deemed to be reliably identified and stratigraphically well 
located were included in the age models. 
Age-depth models were created using the CHRONOS 
ADP application with an interactive line of correlation 
(LOC) drawn through the most reliable stratigraphic event 
data points (see http://www.chronos.org). Stratigraphic 
uncertainty is plotted as vertical bars to show the thickness 
between samples containing the datum marker and the next 
sample below or above where the datum marker is absent. 
Table 1 lists the bioevents, associated biozones and datum 
ages used in the age models. Bioevent ages originally 
reported relative to previous time scales (e.g., Gradstein and 
others, 1994; Cande and Kent, 1995; Hardenbol and others, 
1998, Chart 5) were converted by J. Ogg, (pers. comm., 
2007) to the Geologic Time Scale 2004 (GTS2004; 
Gradstein and others, 2004) by maintaining the same 
relative position in the polarity chrons and adjusting to 
0.01-m.y. precision. Sources for bioevent depths are cited in 
Tables 2-5. In the present study, we distinguish between 
lowest (LO) and highest (HO) occurrences of marker 
species, which are used to define biozone boundaries within 
the sections, and first-appearance (FAD) and last-appear- 
ance (LAD) datums, which are used to define globally the 
temporal limits of a bioevent. 
As an independent check on the accuracy of the age model, 
we used the interpreted age-depth relationship from age 
164 HUBER AND OTHERS 
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166 HUBER AND OTHERS 
models for each site to generate an estimated age for each 
Campanian-Maastrichtian Blake Nose sample for which 
'*'Sr/'*''Sr data are available (MacLeod and others, 2001a; 
MacLeod and others, 2003). These ages and ratios are then 
plotted against the '*'Sr/'*''Sr sea water curve of McArthur and 
Howarth (2004). Like the age model, this Sr-curve is 
cahbrated to the time scale of Gradstein and others (2004). 
However, because of a consistent offset in similarly aged 
samples observed between samples from a number of sites 
analyzed at the University of North CaroHna and those used 
to define the mean Late Cretaceous seawater strontium 
curve, the reference curve was shifted by 0.000020 toward 
higher values (MacLeod and others, 2003). 
BIOZONATION 
The planktonic foraminiferal zonal scheme outlined 
below is based on the standard tropical/subtropical scheme 
of Robaszynski and Caron (1995), which was established 
for the families Globotruncanidae and Heterohelicidae 
based on observations from Cretaceous sections in the 
Mediterranean region. This scheme has been modified to 
improve reliability of correlation among the Blake Nose 
drill sites by including recognition of a new Pseudoguembe- 
lina palpebra Partial-range Zone between the Globotrunca- 
nella havanensis and Racemiguembelina fructicosa Zones. 
Other modifications and refinements are noted in the 
remarks subsection of the zonal descriptions below. Ages of 
the zonal marker datums and sources for those ages are 
cited in Table 1. Biostratigraphic subdivisions of each 
Blake Nose drill site are correlated relative to the drill site 
magnetostratigraphy and the Robaszynski and Caron 
(1995) biozonation in Figures 2-5. Datums used to define 
the calcareous nannofossil tropical/subtropical biozona- 
tions of Sissingh (1977) and Perch-Nielsen (1985), as 
adopted by Self-Trail (2002) and identified in this study, 
are listed in Table 1 and presented in Figures 2-5. 
Globotvuncana ventvicosa Partial-range Zone (=Glohotruncana 
ventHcosa Interval Zone of Robaszynski and Caron, 1995) 
Definition. Biostratigraphic interval from the lowest-occur- 
rence of the nominate species to the lowest occurrence of 
Radotruncana calcarata. 
Magnetochronologic calibration. Premoli Silva and Sliter 
(1994) record the LO at the same level as the base of Chron 
C33n in the Bottaccione section. 
Age Estimates. Base 79.54 Ma, top 75.57 Ma. 
area, G. bulloides, G. hilli, G. linneiana, Globotruncanita 
stuartiformis, and Contusotruncana fornicata. Heterohelicid 
species include Heterohelix globulosa and Pseudotextularia 
nuttalli. 
Radotruncana calcarata Taxon-range Zone {=Globotruncana 
calcarata Total Range Zone of Robaszynski and 
Caron, 1995) 
Definition. Biostratigraphic interval comprising the total 
range of the nominate species (Fig. 2). 
Magnetochronologic calibration. Based on the study of 
Premoh Silva and SHter (1994), the LO and HO of R. 
calcarata are estimated at 76% and 92%, respectively, above 
the base of Chron C33n in the Bottaccione section. At ODP 
Site 1050 the LO of K calcarata correlates with a normal 
polarity zone assigned to C33n (Fig. 4). 
Age Estimates. Base 75.57 Ma, top 75.07 Ma. 
Remarks. The nominate species is a rare but conspicuous 
element found throughout this zone. The stratigraphic 
range of R calcarata in the Bottaccione section may be 
underestimated because of difficulty in making unambigu- 
ous identification of specimens with spines in thin section 
(Premoli Silva and Sliter, 1994). Thus, ages for its FAD and 
LAD may be underestimated. 
Characteristic globotruncanid species found in this zone 
include Globotruncana area, G. angulata, G. atlantica, G. 
bulloides, G. insignis, G. orientalis, Globotruncanita stuarti- 
formis, Contusotruncana fornicata and C. patelliformis. 
Characteristic heterohelicid species include Heterohelix 
globulosa and Pseudotextularia nuttalli. 
LOs observed within this zone include Planoglobulina 
manuelensis, P. riograndensis, Pseudoguembelina costulata, 
Gublerina acuta and Globotruncanella havanensis. 
Globotruncanella havanensis Partial-range Zone 
{=Globotruncanella havanensis Interval and Partial 
Range Zone of Robaszynski and Caron, 1995) 
Definition. Biostratigraphic interval containing the partial 
range of the nominate taxon from the HO of Radotruncana 
calcarata to the LO of Pseudoguembelina palpebra (Fig. 2). 
Magnetochronologic calibration. See above for base and 
below for top of zone. 
Age Estimates. Base 75.07 Ma, top 71.64 Ma. 
Remarks. Although the zonal marker was found only in one 
sample, the zonal interval is assigned to all of Core 1050C- 
19R based on the presence of Globotruncanita subspinosa, 
G. atlantica, G. elevata, Contusotruncana patelliformis and 
C. plummerae and the absence of Radotruncana calcarata. 
The lower part of this zone at Site 1050 is truncated by an 
unconformity. This zone is absent from the other Blake 
Nose drill sites. 
In addition to the species listed above, characteristic 
globotruncanids within this zone include  Globotruncana 
Remarks. The nominate species is relatively rare within this 
zone, whereas globotruncanids including Globotruncana 
area, G linneiana, G. bulloides, Contusotruncana fornicata 
and Globotruncanita stuartiformis are quite common. 
Among the heterohehcids, Heterohelix globulosa is common 
and Pseudotextularia nuttalli, Laeviheterohelix glabrans and 
Planoglobulina riograndensis are present but relatively rare. 
Numerous lowest occurrences are recorded within this 
zone. Species with LOs near the base of the zone include 
Pseudoguembelina  excolata,   Globotruncanita stuarti and 
BLAKE NOSE CHRONOSTRATIGRAPHY 167 
TABLE 2.    Biostratigraphic datums used to define the age-depth curve for ODP Hole 1049C. 
Datum type Event Plot-code Young age (Ma) Top depth (mbsf) Bottom depth (mbsf) 
KPB K/P boundary' KPB 65.50 113.07 113.07 
M bChron C29r- bC29r 65.86 113.89 115.24 
F b G.aegyptiaca' bGa 73.27 120.18 120.68 
N b M. prinsii" bMp 65.81 123.61 125.08 
F b P. hariaensis^ bPh 66.78 123.61 124.10 
N b C. kamptneri* bCk 67.44 125.08 125.56 
N b M. muru^ bMm 68.51 125.08 125.56 
F b A. mayaroensis^ bAm 68.72 125.08 125.56 
F b R fructicosa^ bRf 69.62 125.56 126.54 
F h P. acervulinoides" bPa 72.35 125.56 126.54 
F b P. elegans' bPel 75.07 125.56 126.54 
F b G. gansserP bGg 72.35 128.49 129.47 
F b P. excolata' bPex 73.27 129.69 130.20 
F t R. calcarata' tRc 75.07 130.20 130.70 
N t E. eximius^ tEe 75.31 130.70 131.97 
N b Q. trifidum'' bQt 76.29 130.70 131.97 
F b R. calcarata^ bRc 75.57 132.33 132.40 
'Norris and others, 1998 
"Oggand Bardot, 2001 
'This study 
"Self-Trail, 2002 
^Watkins in Norris and others, 1998 
Rugoglobigerina hexacamerata; LOs in the middle of the 
zone include Globotruncanella petaloidea and Gublerina 
robusta. 
Pseudoguembelina palpebva Partial-range Zone (defined 
herein; different denotation than Pseudoguembelina palpebra 
Zone of Li and Keller, 1998) 
Definition. Biostratigraphic interval from the LO of 
Pseudoguembelina palpebra to the LO of Racemiguembelina 
fructicosa. 
Magnetochronologic calibration. At Site 1050, the LO of P. 
palpebra occurs 21 cm above the midpoint depth of Chron 
C32n.lr (this study). The LO of R. fructicosa correlates 
with the upper third of Chron C31r in southern Europe 
(PremoH Silva and Sliter, 1994; Robaszynski and Caron, 
1995) and in the subtropical North Atlantic Ocean (this 
study). The LO of i?. fructicosa within the middle of Chron 
C31n in the mid-latitude South Atlantic Ocean (Li and 
Keller, 1998) may be the result of poleward diachroneity in 
its distribution. 
Age Estimates. Base 71.64 Ma, top 69.62 Ma. 
Remarks. The LO of the nominate taxon is determined by 
the appearance of a finely costate biserial heterohelicid that 
has a rapid chamber-size increase in the early ontogeny and 
the distinct presence of at least one supplementary aperture. 
These early forms strongly resemble the holotype of 
Pseudoguembelina polypleura Masters, 1976, which is 
considered a junior synonym of P. palpebra by most 
authors (e.g., see Nederbragt, 1991). Later forms tend to 
show increased pinching of the final chambers, greater 
inflation of the prepenultimate chambers, a more coarsely 
costate test, and earlier ontogenetic appearance of the 
supplementary apertures than early forms. However, the 
change is gradual through the section, with a range of 
morphologies possible in any given sample. 
The LO of P. palpebra is consistently found in low to 
moderate abundance between the HO of R calcarata and 
the LO of R fructicosa at all of the Blake Nose drill sites 
and is recorded just above the LO of Gansserina gansseri in 
Hole 1049C. Because G. gansseri has a spotty distribution in 
the Blake Nose samples and is very rare when it is found, 
the LO of P. palpebra is considered a more reliable 
biomarker than the LO of G. gansseri for correlation 
within the uppermost Campanian interval. The FAD of P. 
palpebra is estimated as 71.64 Ma based on ages averaged 
TABLE 3.    Biostratigraphic datums used to define the age-depth curve for DSDP Hole 390A. 
Datum type Event Plot-code Young age (Ma) Top depth (mbsf) Bottom depth (mbsf) 
KPB K/P boundary KPB 65.50 111.87 112.20 
F b P. hariaensis bPh 66.78 125.01 125.77 
N b C. kamptneri bCk 67.44 125.77 125.87 
N b M. murus bMm 68.51 125.77 125.87 
F b A. mayaroensis bAm 68.80 125.77 125.87 
F b R. fructicosa bRf 69.56 126.36 126.85 
F t R. calcarata tRc 75.07 139.32 139.48 
F b R. calcarata bRc 75.57 140.14 140.31 
F b G.aegyptiaca bGa 73.27 124.37 125.01 
F b P. elegans bPel 75.07 125.77 126.36 
168 HUBER AND OTHERS 
TABLE 4.    Biostratigraphic datums used to define the age-depth curve for ODP Hole 1050C. 
Datum type Event Plot-code Young age (Ma) Top depth (mbsf) Bottom depth (mbsf) 
F K/P boundary' KPB 65.50 405.97 405.97 
N b M. prinsiP bMp 65.81 427.00 428.50 
F b P. hariaensis^ bPh 66.78 427.92 428.93 
N b C kamptnerf bCk 67.44 427.00 428.50 
N b M. murus^ bMm 68.51 446.30 448.20 
N b L. quadratus^ bLq 68.70 450.50 452.20 
F b A. mayaroensis" bAm 68.72 451.51 451.82 
M bCSln" bC31n 68.79 452.47 453.03 
F b R. fructicosa^ bRf 69.62 456.29 462.17 
N t R. levis^ tRl 69.44 475.20 478.20 
M bCSln.lr" bC32n.lr 71.47 476.46 477.56 
N t T. phacelosus^ tTp 71.80 475.20 478.20 
F b G. gansserP bGg 72.35 473.70 474.30 
F b P. acervulinoides^ bPa 72.35 462.17 463.55 
F b G. aegyptiaca^ bGa 73.27 476.55 478.15 
F b P. excolatd' bPe 73.27 476.55 478.15 
F b P. elegans' bPel 75.07 467.20 468.70 
F t R. calcarata' tRc 75.07 478.15 478.86 
N t A. parcus* tAp 74.65 478.20 478.90 
F b R. calcarata^ bRc 75.57 478.86 481.69 
N t E. eximius^ tEe 75.31 478.90 482.30 
N h Q. sissingh^ bQs 77.10 491.30 491.40 
F b G. ventricosa^ bGv 79.54 484.56 491.02 
'Norris and others, 1998 
"Self-Trail, 2002 
^This study 
*Ogg and Bardot, 2001 
^Watkins in Norris and others, 1998 
from its LOs at ODP Sites 1049 and 1050, which differ by 
only 0.21 m.y. (Table 7). The age of the lowest occurrence 
of P. palpebra in Hole 1052E is not calculated because of an 
unconformity separating upper Campanian from lower 
Cenomanian sediments. 
Globotruncanid assemblages in the P. palpebra Zone are 
very similar to those found in the underlying G. 
havanensis  Zone.   Globotruncana  area,   G.   bulloides,   G. 
linneiana and Globotruneanita stuartiformis are most 
abundant and G. hilli and C. patelliformis increase in 
abundance up section. Heterohelicids are dominated by 
Heterohelix globulosa and Pseudotextularia nuttalli. Pseu- 
doguembelina palpebra, P. eostulata, Heterohelix navar- 
roensis, H. labellosa, Gublerina acuta, Planoglobulina 
manuelensis, and P. riograndensis occur consistently in 
low to moderate abundance. 
TABLE 5.    Biostratigraphic datums used to define the age-depth curve for ODP Hole 1052E. 
Group Event Plot Code Young Age (Ma) Top depth (mbsf) 
302.18 
302.79 
324.60 
328.88 
335.62 
343.68 
351.80 
367.90 
379.01 
385.00 
386.26 
389.92 
400.12 
468.35 
386.67 
414.52 
473.70 
474.00 
423.27 
Bottom depth (mbsf) 
KPB 
M 
F 
F 
M 
M 
N 
N 
F 
N 
M 
N 
F 
M 
F 
F 
F 
N 
F 
k/t boundary' KPB 
b C29r- b29r 
b M. prinsiP bMp 
b P. hariaensi'i* bPh 
base C30rf b30n 
base C30r2 b30r 
b C kamptnerP bCk 
b M. murus" bMm 
b A. mayaroensi!^ bAm 
b L. quadratus^ bLq 
b C31n2 bC31n 
t R. levitP tRl 
b R. fructicosa* bRf 
b C31r- bC31r 
b P. acervulinoidea* bPa 
b G. aegyptiaccP bGa 
b G. gansserP bGg 
t T. phacelosus^ tTp 
b P. elegans* bPel 
65.50 
65.86 
65.81 
66.78 
67.70 
67.87 
67.44 
68.51 
68.72 
68.70 
68.79 
69.44 
69.62 
70.96 
72.35 
72.35 
72.35 
71.80 
75.07 
302.18 
309.70 
326.00 
330.32 
338.71 
349.30 
352.90 
377.10 
380.28 
386.70 
386.73 
394.28 
411.99 
478.35 
394.26 
418.50 
474.30 
474.40 
424.22 
'Norris and others, 1998 
"Ogg and Bardot, 2001 
^Self-Trail, 2002 
*This study 
'Watkins in Norris and others, 1998 
BLAKE NOSE CHRONOSTRATIGRAPHY 169 
1049A 
126 - 
Hoan. CP28 Pa 
i 
128- 1 
- ^ .<o 
130- c to 
: w 
'-*-* TO CD 
132- o CN 
? U 
-c: 
-4?" C  1 
_ (/) n 
U4- 1 
136- 1 
138-^ 1 a ma. 
140- 1 LO CO 3. 
142- 1 Q. E 
CD 
o 
(Si 
O 
O 
144- 
O s 
- m Alb. 
1049B 
10 
Dan. C P7fi Pa 
CO 
CO !_ o C 
ro CO U) 
-I?? CM 10 jz 
o CD CB 
L_ <M (rt o CL 
CD o 
CD 
^ 
^ 
S 
CM 
-Q 
Q. n CO b (D 
o Q. 
O / / 
Alb. 
1049C 
^^Dan. CP28 Pa 
114-^ 1 
116- 1 CO 
^H c JO CO 
118- 
CD 
C\J en 
?1 JZ CO C: 
CD m 
120- ^ ^M  ^ CM f ?? s: 
^1  (/> 
H   CD O IX. 
122- S   CD 
124- 1 CO 
JM t 
126- 91 o ?i: 
^H ID Q. 
^^H CM CT3 
128- ^ 1 d CO 
130- 
S CD o 
O 
i3) 
TO 
JN ^ OJ TO fllo !) 
132- 
WAIb. 
^JJ^ O 
390A 
FIGURE 2. Comparison of meters-below-seafloor depths for planktonic foraminiferal and calcareous nannofossil biozones in ODP Site 1049 and 
DSDP Hole 390A showing core recovery in each hole (black = recovered intervals). Dashed line correlates the Cretaceous/Paleogene boundary, and 
dotted lines correlate major unconformities at the base of the Ahathomphalus mayaroensis Biozone and Radotruncana calcarata Biozone. Planktonic 
foraminiferal zonal datums and SEM images are shown to the right. See Table 1 for full spelling and definitions of biozones. 
Lowest occurrences within the lower part of this zone 
include Pseudoguembelina kempensis and Racemiguembelina 
powelli. LOs in the upper part of the zone include 
Planoglobulina multicamerata, Pseudotextularia intermedia, 
P. brazoensis and Contusotruncana contusa. 
Racemiguembelina fiucticosa Partial-range Zone (base 
different, top same as Racemiguembelina fiucticosa 
Partial-range Zone of Robaszynski and Caron, 1995) 
Definition. Biostratigraphic interval from the LO of 
Racemiguembelina fiucticosa to the LO of Ahathomphalus 
mayaroensis. 
Magnetochronologic calibration. See above for LO of R. 
fiucticosa. In the Italian Bottaccione section, the LO of A. 
mayaroensis correlates with the base of Chron C31n 
(Premoli Silva and Sliter, 1994), whereas it has been 
reported in lower to middle Chron C31r in the South 
Atlantic Ocean (Huber, 1990; Li and Keller, 1998). 
Age Estimates. Base 69.62 Ma, top 68.72 Ma. 
Remarks. The LO of R. fiucticosa is differentiated from its 
ancestor, R. powelli, by having smaller, more numerous 
multiserial chambers that form a more circular test outline 
in top view and are connected by a sieve plate (Nederbragt, 
1991). However, presence of intermediate forms may cause 
some uncertainty in identifying this datum. The nominate 
species is rare in the lower part of the zone and becomes 
increasingly abundant in the upper part. 
Characteristic globotruncanid species include Globotrun- 
cana area, G. conica, G. hilli, Gobotruncanita stuartiformis 
and Contusotruncana contusa. Globotruncana bulloides 
becomes very rare in the upper part of the zone. 
Heterohelicids are dominated by Heterohelix globulosa, H. 
striata and H. navarroensis, whereas Heterohelix labellosa, 
Pseudotextularia elegans, Planoglobulina multicamerata and 
Pseudoguembelina palpebra occur consistently in low to 
moderate abundance. Planoglobulina manuelensis becomes 
less abundant in the upper part of this zone. 
LOs within this zone include Heterohelix semicostata, 
Planoglobulina acervulinoides and Rugoglobigerina rotun- 
data. The HO of Contusotruncana fornicata is recorded in 
the middle of this zone. 
170 HUBER AND OTHERS 
Hole1052E Hole1050C Hole 1049C 
66- 
67- 
68-S 
69- 
70- 
71- 
72- 
73 
74- 
75- 
76 
hariaensis 
 mayar. 
fructic. - 
palpebra 
calcarata 
gpiriKKf^n 
_ 36R ?  greenhornensis (Cenomanian) 
rischi (Albian) 
FIGURE 3. Correlation of upper Campanian-Maastrichtian meters-below-seafloor depths, core number, amount of recovered core (white = coring 
gap), and planktonic foraminiferal biozones for the Leg 171B drill sites. Dashed lines indicate that the zonal boundary occurs at an unconformity. See 
text for complete spelling and definitions of planktonic foraminiferal biozones. 
BLAKE NOSE CHRONOSTRATIGRAPHY 171 
M^ ^ (/) n> XJ > 
E o <> 
'?' 0) 
r Q: 
?*-> 
Q. 
o 
Q O 
FIGURE 4. Age-depth plot for Hole 1049C. Horizontal axis shows standard tropical/subtropical planktonic foraminiferal and calcareous 
nannofossil biozones correlated to the Gradstein and others (2004) geologic time scale; vertical axis shows the Blake Nose core-depths, core recovery, 
magnetostratigraphic interpretations and planktonic foraminiferal and calcareous nannofossil biozones. A line of correlation (LOG) is drawn through 
the most reliable stratigraphic event data points. Calculated sedimentation rates are shown for each change in slope of the LOG. Stratigraphic 
uncertainty is plotted as vertical bars for each datum to show the thickness between samples containing the datum marker and the next sample below 
or above where the datum marker is absent. Wavy lines represent major unconformities. Magnetic polarity intervals are represented by black for 
normal, white for reversed and diagonal lines for uncertain. Full spelling and explanation of the species datums are presented in Table 1. Inoceramid 
bivalve extinction level identified in the present study. 
Abathomphalus mayaroensis Partial-range Zone (base same, 
top different from Abathomphalus mayaroensis 
Partial-range Zone of Robaszynski and Caron, 1995) 
Definition. Biostratigraphic interval from the LO of 
Abathomphalus mayaroensis to the LO of Pseudoguembelina 
hariaensis. 
Magnetochronologic calibration. See above for base. The 
LO of P. hariaensis has been correlated with middle Chron 
C30n in the Mediterranean region (Robaszynski and 
Caron, 1995) and lower Chron C30n in the mid-latitude 
South Atlantic Ocean (Li and Keller, 1998). 
Age Estimates. Base 68.72 Ma, top 66.78 Ma. 
canid species include Globotruncana area, Globotruncanita 
stuartiformis, G. stuarti and Contusotruncana contusa. 
Heterohelicids are dominated by Heterohelix globulosa, H. 
navarroensis, H. planata, H. striata and Racemiguembelina 
fructicosa, whereas Heterohelix labellosa, Pseudoguembelina 
excolata, P. palpebra, Pianoglobulina multicamerata and 
Pseudotextularia nuttalli occur consistently in low to 
moderate abundance. Rugoglobigerina rugosa and R. 
hexacamerata are also common in this zone. 
The LO of Trinitella scotti is recorded in the middle of the 
A. mayaroensis Zone. 
Pseudoguembelina hariaensis Partial-range Zone 
(=Pseudoguembelina hariaensis Partial-range Zone of 
Robaszynski and Caron, 1995) 
Remarks. The nominate taxon occurs consistently in low 
abundance throughout this zone. Characteristic globotrun- 
Definition.  Biostratigraphic interval from the LO of the 
nominate species to the extinction of most Cretaceous 
172 HUBER AND OTHERS 
Age-Depth Plot for Hole 390A 
9.92m/m.y. 
bVlm i,Am QlbCa 
D Forams 
O Nannos 
O K-P boundary 
mbFcl 
K-H boundar}' 
2.49 m/m.y. 
1.67 m/m.y. 
bRc 
P. har.   A. mayaroen. fruc.       G. gansseri aeg.   hav.  calc.     ventr. 
CC26a     CC25C b   CC25a CC24 
C30 C31 
MaastrichtJan 
CC23 CC22 CC21 
C32 C33 
1-r I I I I 
Campanian 
66       67 68 69       70 71 72        73        74       75 
I  M I M  I  I 
76 Ma 
FIGURE 5.   Age-depth plot for Hole 390A. Inoceramid bivalve extinction level identified by MacLeod and others (2000). Campanian unconformity 
identified based on correlation with Site 1049 sections in the absence of datum control points. See caption of Figure 4 for further explanation. 
planktonic foraminifera at the Cretaceous-Paleogene 
boundary. 
Magnetochronologic calibration. See above for base. Top 
correlated with lower Chron C29r (Premoli Silva and Sliter, 
1994). 
Age Estimates. Base 66.78 Ma, top 65.50 Ma. 
Remarks. The nominate taxon occurs consistently through- 
out the interval in relatively moderate abundance. 
Globotruncanid species include common Globotruncanita 
stuartiformis, Globotruncana area and Contusotruncana 
contusa; rare to moderately abundant Globotruncanita 
stuarti, Globotruncana falsostuarti, G. esnehensis, G. conica 
and G. angulata; and very rare Abathomphalus mayar- 
oensis, Globotruncana dupleublei and G. insignis. Hetero- 
helicids are dominated by Heterohelix globulosa and 
include relatively common Heterohelix labellosa, Racemi- 
guembelina fructicosa, Pseudotextularia elegans and P. 
nuttalli. 
The HOs of Globotruncana linneiana and Contusotruncana 
patelliformis occur in the base and middle of this zone, 
respectively. 
Plummerita hantkeninoides is absent from all of the Blake 
Nose sites despite the presence of sediments spanning the 
age range of this species, which evolved within the last 
300 k.y. of the Maastrichtian (Abramovich and Keller, 
2002). This species apparently preferred to live in eutrophic 
shelfal to upper-slope continental margin environments 
(e.g., Abramovich and others, 1998; Abramovich and 
Keller, 2002; MacLeod and others, 2007) and has not been 
reported from open-ocean pelagic carbonate sediments. 
AGE MODELS 
Datums determined for Campanian-Maastrichtian 
planktonic foraminifera and calcareous nannofossils and 
the levels of magnetic polarity reversals obtained from 
DSDP/ODP sites on the Blake Nose provide the basis for 
construction of the age-depth models presented in Fig- 
ures 4-7. Age assignments, lowest and highest occurrence 
BLAKE NOSE CHRONOSTRATIGRAPHY 173 
v..? 18.Wm/m.y. Age-Depth Plot for Hole 1050C 
? Planktonic Foramiiiifera 
O Calcareous nannofossils 
D Magnetic reversal 
T K-Pbwindar) 
I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I 
71        72       73        74       75        76       77       78       79 
FIGURE 6.   Age-depth plot for Hole 1050C. Inoceramid extinction level identified by MacLeod and Huber (2001b). See caption of Figure 4 for 
further explanation. 
depths, and reference sources are presented in Tables 2-5. 
Sr isotopic data are used as a means of independently 
evaluating the model and are discussed below. 
SITE 1049 
Cretaceous sediments from the three holes drilled at Site 
1049, which are located about 10 m apart from each other, 
are precisely correlated using the base of the impact bed at 
the Cretaceous/Paleogene (K/P) boundary as a datum plane 
(Fig. 2). Constructing a precise age model for this site (and 
for Hole 390A) is difficult as the section is relatively thin 
(reducing stratigraphic resolution) and contains significant 
coring gaps and disturbed bedding that may indicate 
slumping in places. Sediment thickness between the K/P 
boundary and the unconformity bounding the late Campa- 
nian Radotruncana calcarata Zone and the early Albian 
Hedbergella rischi Zone varies between 17.98 and 19.26 m 
in the three drillholes, but it is about 10-m thicker in Hole 
390A due to a thicker interval of Campanian sediment 
(Fig. 2). Sub-bottom depths to the K/P boundary differ 
between these holes by as much as 14.8 m. This offset 
probably resulted from error in calculating the depth to the 
seafloor surface, as the method used at Site 1049 depended 
on estimation of when a reduction in drill string weight 
occurred (Norris and others, 1998, p. 49), which can be 
imprecise when drilling in soft sediment. Comparison of 
sub-bottom depths for planktonic foraminiferal and cal- 
careous nannofossil datums for these holes show offsets 
that are similar to the boundary offsets. Planktonic 
foraminiferal and calcareous nannofossil datums were 
determined with greatest precision at Hole 1049C, which 
is used as the basis for constructing the age model for Site 
1049 (Fig. 4). Table 2 lists all datums included in this age 
model along with the less precisely determined datums used 
to determine zonal boundary depths for Holes 1049A and 
1049B (Fig. 2). 
Despite the problems outlined, the age model for Hole 
1049C is constrained by a number of reliable datums. The 
depths of the K/P boundary and the Chron C29r/C30n 
reversal in the uppermost Maastrichtian establish a 
sedimentation rate of 4.17 m/m.y. Below the base of Chron 
C29r, the estimated sedimentation rate increases to 
10.11 m/m.y., as determined by passing the LOC through 
the FAD of Pseudoguembelina hariaensis. This datum 
occurs at the same level as the FAD of the calcareous 
nannofossil Micula prinsii and just above a distinct 
sediment color change at 125.48 mbsf that is interpreted 
as a hiatal surface. Based on co-occurring FADs of four 
planktonic foraminiferal and calcareous nannofossil da- 
tums, this hiatus is estimated to span the interval from 66.92 
to 68.95 Ma. 
Between 68.95 Ma and 73.90 Ma, planktonic foraminif- 
eral datums line  up to  define  a  LOC  that  suggests 
174 HUBER AND OTHERS 
kbC29r 
? 37.89 m/m.y. Age-Depth Plot for Hole 1052E 
bC30n 
bC30r 
1 m/m.y. 
O Planktonic Foraminifera 
O Calcareous nannofossils 
? Magnetic reversal 
T K-P boundary 
FIGURE 7.   Age-depth plot for Hole 1052E. Inoceramid bivalve extinction level identified by MacLeod and Huber (2001b). See caption of Figure 4 
for further explanation. 
sedimentation rates were much slower (1.03 m/m.y.) below 
the color change than above it (10.11 m/m.y.). Disturbed 
bedding in this interval is suggestive of slumping, but there 
is no biostratigraphic evidence for mixing or repetition of 
strata. A short (?1.14 m.y.) hiatus is placed between the 
base of the G. havanensis Zone and top of the R. calcarata 
Zone, below which is a 2-m interval that spans most of the 
R calcarata Zone. An ~34-m.y. unconformity separates 
upper Campanian from lower Albian sediments. 
The LOs of Planoglobulina acervulinoides and Pseudo- 
textularia elegans are estimated as 69.62 Ma according to 
the LOC for Hole 1049C. This age is much younger than 
the FAD ages that have been previously used for these 
species (Table 1). 
SITE 390A 
The age-depth curve for Hole 390A is very similar to that 
of Hole 1049C. Differences between the two curves are 
attributed to inclusion of fewer calcareous nannofossil 
datums and absence of the Chron C29r/C30n paleomag- 
netic control point in Hole 390A (Fig. 5). The K/P 
boundary, which is used as a datum plane for correlation 
of the three holes at Site 1049, was not recovered intact at 
Site 390 because of coring disturbance (Benson and others, 
1978). The boundary is placed between 145 and 149 cm in 
Section 390A-11-5 (111.95-112.00 mbsf), where there is a 
sediment color change and a mixture of planktonic 
foraminifera and calcareous nannofossils of latest Maas- 
trichtian and earliest Danian age (Benson and others, 1978). 
The age model for Hole 390A indicates an initially fast 
sedimentation rate of 10.11 m/m.y. between the K/P 
boundary (KPB) and the mid-Maastrichtian unconformity, 
which is marked by a sharp color change at 125.87 mbsf. 
The unconformity is estimated to span the interval between 
66.94 and 68.85 Ma, with a 1.91-m.y. duration. Below the 
unconformity, the sedimentation rate slows to about 
1.03 m/m.y. A brief unconformity between 75.05 and 
73.90 Ma is followed by a short interval of sedimentation 
and then a major unconformity between 75.57 Ma and 
110.00 Ma. 
There are significant differences in depths below the 
seafloor between Holes 390A and 1049C that should be 
considered when correlating between these two holes 
(Fig. 2). First, assuming the KPB is nearly complete at 
Hole 390A, its depth is 1.08 m above the base of the tektite 
bed at Hole 1049C. Second, the depth of the mid- 
Maastrichtian unconformity Hole 390A is 1.47 m below 
that in Hole 1049C. Finally, biozones below the mid- 
Maastrichtian unconformity at Site 390A thicken with 
depth, such that the top of the K calcarata Zone is 8.95 m 
deeper than in Hole 1049C. These differences suggest that 
BLAKE NOSE CHRONOSTRATIGRAPHY 175 
the position of Hole 390A must be offset relative to Site 
1049, despite use of the same geographic coordinates. These 
differences underscore the problems of resolving short 
intervals of time in sections with slow sedimentation rates 
and potential sedimentological complications. 
SITE 1050 
The most complete Campanian-Maastrichtian record at 
the Blake Nose occurs at Site 1050, extending ?79 m from 
the G. ventricosa Zone to the P. hariaensis Zone. Although 
the K/P boundary is biostratigraphically complete, no 
impact ejecta were observed in sediments above or below 
the boundary layer, suggesting that the impact bed may 
have been slumped away (Norris and others, 1998). As 
observed at Site 1049, the LOs of M. prinsii and P. 
hariaensis occur in close proximity to each other, and the 
latter is used as a control point for the LOC. The 
sedimentation rate for this interval is estimated as 
18.10 m/m.y. A 0.66-m.y. hiatus is interpreted to occur at 
a possibly slumped interval at 427.75 mbsf. Tie points 
linking the LO of C. kamptneri and the Chron C31n/C31r 
boundary are supported by several calcareous nannofossil 
and planktonic foraminiferal datums, and indicate a 
sedimentation rate of 18.33 m/m.y. within the A. mayar- 
oensis Zone. 
From the base of Chron C31n to the base of the G. 
havanensis Zone, the planktonic foraminiferal and calcar- 
eous nannofossil datums indicate a sedimentation rate of 
8.94 m/m.y. The LOs of Planoglobulina acervulinoides and 
Pseudotextularia elegans are about 69.98 and 68.76 Ma, 
respectively, according to the LOC at Hole 1050C. These 
ages are considerably younger than the FAD ages that have 
been used previously for these species (Table 1). 
Similarly, the LO of Reinhardtites levis at Site 1050 is 
recorded at a level that projects to about 2.02 m.y. earlier 
than its previously assigned FAD age. 
A hiatus estimated to range from 75.04 to 71.62 Ma 
spans the lower G. havanensis Zone and upper R. calcarata 
Zone. Below this hiatus is a 13.42-m interval comprising the 
interval from the R. calcarata Zone to the G. ventricosa 
Zone and for which the estimated sedimentation rate is 
6.50 m/m.y. This interval is underlain by a disconformity 
? 10 m.y. in duration that separates upper Campanian from 
lower Cenomanian sediments. 
SITE 1052 
The 172-m-thick, late Campanian-Maastrichtian interval 
at Hole 1052E ranges from the G. havanensis Zone to the P. 
hariaensis Zone. The K/P boundary was not recovered in 
this hole, probably because of poor core recovery, but the 
upper Maastrichtian is considered biostratigraphically 
complete (Norris and others, 1998). The LOC spanning 
the P. hariaensis Zone is determined from alignment of the 
FAD of P. hariaensis and the base of Chron C29r. As 
observed at Sites 1049 and 1050, the LO of M prinsii is very 
close to that of P. hariaensis, contrary to the 0.54-m.y. age 
difference that has been assigned to these species. Based on 
this curve, we estimate that sediment from the last 150 k.y. 
of the Maastrichtian is missing. The sedimentation rate in 
this interval is calculated as 37.89 m/m.y. As occurs at Sites 
1049 and 1050, a hiatus is recognized just below the LO of 
P. hariaensis and ranges from 66.49 to 67.57 Ma. Align- 
ment of the bases of Chrons C30n and C30r and calcareous 
nannofossil and planktonic foraminiferal datums establish- 
es a sedimentation rate of 45.11 m/m.y. and indicates the 
presence of a hiatus spanning the period from 69.34 to 
68.82 Ma, which is within a slumped interval in Core 
1052E-17. 
Using the FAD of K fructicosa and the base of Chron 
C31r as tie points, the sedimentation rate between the 
lower R. fructicosa Zone and the upper G. havanensis Zone 
is calculated as 50.09 m/m.y. A major unconformity 
that separates the upper G. havanensis Zone from the 
Rotalipora globotruncanoides Zone (lower Cenomanian) in 
Section 1052E-36R-1 is estimated to have a duration of 
?26 m.y. 
A delayed first occurrence at Site 1052 for C kamptneri 
(or unrecorded occurrence) is suggested by an LO that is 
0.59 m.y. younger than the assumed age of its FAD. The 
LOs of P. acervuHnoides and P. elegans are dated as 69.05 
and 68.68 Ma, respectively, according to the LOC for Hole 
1052E. These ages are much younger than the FAD ages 
that have previously been used for this species. 
DISCUSSION 
BlOSTRATIGRAPHIC DATUMS 
The age models constructed for the upper Campanian- 
Maastrichtian interval at each of the Blake Nose drill sites 
demonstrate that the relative order of occurrences and ages 
used for most of the planktonic foraminiferal and 
calcareous nannofossil datums listed in Table 1 are 
consistent and reliable. Moreover, the Maastrichtian 
magnetic-reversal-boundary tie points that are included in 
the age models are collinear with the microfossil datums, 
providing further evidence that the biostratigraphic age 
calibrations are dependable, at least for tropical and 
subtropical oceans. 
Three out of the thirteen calcareous nannofossil species 
used in construction of the age models show significant 
offsets from the age model LOCs from at least one of the 
three drill sites where they have been identified. The HO of 
Reinhardtites levis in Hole 1050C was identified 18.32 m 
lower than the depth predicted from the LOC (Fig. 6) and 
the LO of Ceratolithoides kamptneri was identified 19.41 m 
lower than the depth predicted by the LOC in Hole 1052E 
(Fig. 7). These inconsistencies do not necessarily point to a 
problem with the assigned datum ages, since there is good 
agreement with the age models at the other Blake Nose 
sites. However, at all three Leg 171B drill sites, the assigned 
FAD age for Micula prinsii is consistently younger by about 
0.5 m.y. than the predicted age for its LO. This discrepancy 
is difficult to explain since the M. prinsii datum was 
carefully documented by Henriksson (1993) in multiple 
Atlantic and Pacific Ocean sequences with magnetostrati- 
graphic age control. 
Significant offsets from the age model lines of correlation 
are shown for several planktonic foraminiferal datums at all 
of the Blake Nose sites. Relative to the LOCs for each site, 
the LO of Pseudotextularia elegans projects to ages that are 
176 HUBER AND OTHERS 
5.5 to 6.4 m.y. younger than the assigned datum age, and 
the LO of Pianoglobulina acervulinoides is between 2.4 and 
3.3 m.y. too young. Both of these offsets are probably an 
artifact of inconsistency in taxonomic concepts. The 
confusion with P. elegans stems from a poorly drawn type 
specimen that has been lost. For this species, we follow the 
species concept of Nash (1981), who selected a neotype 
bearing thick, continuous costae. As was noted by 
Nederbragt (1991), P. elegans has a distinctively different 
appearance from the finely costate Pseudotextularia nuttalli, 
and the stratigraphic ranges differ in that the former species 
is restricted to the Maastrichtian and the latter species 
ranges down to the Coniacian. The 75.25-Ma age for the 
FAD of P. elegans that was cited in Chart 5 of Hardenbol 
and others (1998) was most likely based on identification of 
the finely costate P. nuttalli. Based on the Blake Nose age 
models, the LO of P. elegans ranges between 68.68 and 
69.62 Ma, and has a mean age of 69.02 Ma (Table 7). 
Similarly, it is likely that the older age reported for the 
FAD of P. acervulinoides in Gradstein and others (2004) 
is based on a species concept that includes forms here 
assigned to Piano globulina riograndensis. We differentiate 
P. riograndensis as having vermicular ornamentation and a 
greater number of multiserial chambers than does P. 
acervulinoides. Based on our observations, the LO of P. 
acervulinoides occurs between 69.05 and 69.98 Ma, with 
an average age of 69.55 Ma calculated from all the Blake 
Nose drill sites. At the Blake Nose, we have determined 
that the LO of P. riograndensis is in the upper R. calcarata 
Zone, with an FAD of 75.72 Ma. This age is consistent with 
the range reported for P. riograndensis by Nederbragt 
(1991). 
Variations in the LOs of Globotruncana aegyptiaca and 
Gansserina gansseri among sections and relative to the 
established ages of the FADs are explained as sampling 
artifacts due to the scarcity of these taxa at the Blake Nose. 
The LO of G. aegyptiaca in Hole 1049C is recorded in the 
middle of the P. hariaensis Zone, plotting about 7.1 m.y. 
younger than the assigned FAD age; in Hole 1050C, the LO 
of G. aegyptiaca is in the G. havanensis Zone and plots 
1.58 m.y. younger than the assigned age; and in Hole 1052, 
the LO is in the upper P. palpebra Zone and plots 3.35 m.y. 
younger than the assigned age. The LO of G. gansseri is 
recorded close to its FAD age in Hole 1049C, but its 
occurrence in Hole 1050C is over 1 m.y. younger than its 
assigned datum age. In Hole 1052E, the lower range of G. 
gansseri is truncated by a disconformity. 
In addition to the taxa used to constrain the LOC at 
various sections, a number of additional planktonic 
foraminifera are considered reliable regional chronostrati- 
graphic biomarkers. These taxa are listed in Table 7 along 
with their depths and ages calculated from each of the age 
models. Mean ages and maximum difference between ages 
are also presented. Although Contusotruncana contusa has 
been used as a zonal marker taxon in some studies (e.g.. 
Wonders, 1980; Li and Keller, 1998, 1999), the 1.06-m.y. 
difference in ages for its LO at the Blake Nose reflects the 
difficulty in consistently identifying this species because of 
its morphologic variability (e.g., see Kucera and Malmgren, 
1996). 
0.7079 
FIGURE 8. Campanian and Maastrichtian strontium isotopic data 
from MacLeod and ottiers (2003) plotted against age of ttie samples 
estimated using the age models. Seawater curve of McArthur and 
Howarth (2004) shifted by 0.000020 (see text) is shown by the heavy 
curved line with estimated error on the curve represented by the gray 
shading. Error bars on individual data points represent ? 2 s.d. of 
analytical precision. 
COMPARISON BETWEEN AGE MODELS AND SR- 
IsoTOPic DATA 
Agreement between the age models and Sr isotopic data 
is generally excellent (Fig. 8). Because the seawater curve 
was calibrated to the timescale of Gradstein and others 
(2004) separately from data used to construct the age 
models and because Sr-isotopic measurements do not 
depend in any way on chronostratigraphic assignments, 
this comparison is an independent confirmation of the 
general accuracy of the age models. Beyond this confirma- 
tion, the Sr plot indicates intervals where uncertainty in age 
estimates are relatively large (where the age models and Sr 
ages are not congruent) and intervals where age uncertainty 
is likely low (where the age models and Sr ages are 
congruent). 
In this regard, recognition that much of the lower 
Abathomphalus mayaroensis Zone is missing in Hole 
1049C results in better agreement between Sr data and 
biostratigraphy than seen in a similar comparison using a 
simple age model (MacLeod and others, 2003) and suggests 
improved precision of age estimates in the upper Maas- 
BLAKE NOSE CHRONOSTRATIGRAPHY 177 
trichtian in Hole 1049C. The largest discrepancy between 
the two estimates occurs in the lower portion of the section 
in Hole 1049C where Sr-based age estimates that would 
place the samples in the lower Maastrichtian are at odds 
with the presence of the lower Upper Campanian marker R. 
calcarata. Possible explanations for this discrepancy include 
reworking of older zonal markers into younger sediment 
and alteration of original '*'Sr/'*''Sr ratios. The former is 
consistent with disturbed bedding observed in portions of 
Cores 1049C-10 and -11 but is difficult to reconcile with the 
ordered sequence of both highest and lowest occurrences 
that define the LOC. The latter is consistent with the 
coarser nature of the sediment below the color change 
within Core 10 in Hole 1049C, which might allow relatively 
easy circulation of pore fluids carrying a higher '*'Sr/'*''Sr 
ratio. 
Other discrepancies are minor by comparison. Within the 
major slumped interval in Hole 1052E (?69 Ma), two Sr 
analyses suggest the slumped material includes material 
older than the subjacent hemipelagic interval (MacLeod 
and others, 2003) and the five analyses immediately below 
the slump suggest the youngest sediment below the slump 
may be ?0.5 m.y. older than estimated biostratigraphically. 
Similarly, the high-resolution samples bracketing the major 
slump in Hole 1050C suggest bracketing ages up to ?0.5 to 
1.0 m.y. younger than those estimated in the age models. In 
both cases, the presence of slumped intervals and significant 
coring gaps below the LO of Racemiguebelina fructicosa 
affect the precision of the LOC used in the age models for 
these intervals. Finally, the highest point in Hole 1052E 
suggests that the hiatus spanning the K/P boundary in this 
hole could be slightly longer than estimated, but coring 
gaps in cores 1052E-18 and -19 again limit the precision 
possible in this interval. 
age estimates presented are equivocal as to whether these 
occurred as discrete local events or are correlative and 
potentially related to regional paleoceanographic changes. 
Several slumps in Hole 1052 have no apparent counterparts 
in the other sites and, as discussed above, it is difficult to 
evaluate the nature of disturbed bedding (e.g., drilling 
disturbance or slumping) in the lower Maastrichtian at 
Hole 390A and Site 1049. On the other hand, the mid- 
Maastrichtian hiatus at Site 390A/1049 and the missing 
section in the major slump in Hole 1052E have very similar 
age estimates at their bases. Further, if Sr ages for the major 
slump in Hole 1050C are more accurate than the age 
models, this interval would correlate closely with the slump 
in Hole 1052E. Regardless, the continuity of all age 
estimates?above and below the slumps and hiatuses? 
supports the conclusion of MacLeod and others (2003) that 
the pre-KPB slumped intervals on the Blake Nose were not 
generated by seismic shaking during the K/P impact event 
as had been proposed based on geophysical data (Klaus 
and others, 2000; Norris and others, 2000; Norris and Firth, 
2001). 
At all four sites on the Blake Nose, the oldest Campanian 
sediments are bounded below by major unconformities. The 
age models constructed for these sites in this study and by 
previous workers (Bellier and others, 2000; Petrizzo and 
Huber, 2006) indicate that this unconformity spans the 
period from about 76-110 Ma at Site 1049, 77-87 Ma at 
Site 1050, and 72-97 Ma at Site 1052. Closing of east-west 
gateways to Tethyan circulation and opening of an 
increasingly unrestricted north-south passage through the 
tropical Atlantic gateway are possible ultimate causes for 
these unconformities. Because this study only examined 
material above the unconformity, though, we lack obser- 
vations that meaningfully address the issue. 
SEDIMENTATION HISTORY 
The age-depth curves generated from the Blake Nose 
sites suggest a varied depositional history in the upper 
Campanian and Maastrichtian across the Blake Nose depth 
transect and through time. At the deepest and most- 
offshore site (Sites 1049 and 390), the upper Maastrichtian 
sedimentation rate is relatively high (?10.11 m/m.y.) for a 
sequence with almost no terrigenous clastic content. This 
interval could indicate a period of increased calcareous 
plankton productivity, or it could reflect deposition during 
a period characterized by both downslope and pelagic 
input, and it could be related to hiatuses observed within 
the late Maastrichtian at Sites 1050 and 1052. However, 
core photographs from Cores 1049C-8 through -10 do not 
show slump features nor is there microfaunal evidence for 
downslope transport. The dramatic slowing in sedimenta- 
tion rate from 10.1 Im/m.y. to 1.03 m/m.y. across the 66.94- 
68.85 Ma unconformity at Site 1049 (Fig. 4) suggests that 
the cause(s) of high sedimentation rates ceased prior to the 
K/P boundary. Study of benthic foraminiferal assemblages 
could help determine whether significant bottom-water 
changes occurred across this unconformity, which is evident 
at all three Blake Nose drill sites. 
Although there are several slumped intervals in the upper 
Campanian-Maastrichtian cores at Sites 1050 and 1052, the 
PALEOCEANOGRAPHIC AND BIOTIC EVENTS 
Stable isotope data generated from the upper Campa- 
nian-Maastrichtian interval along the Blake Nose depth 
transect are replotted in Figures 9 and 10 using ages 
calculated from the new age models discussed above. For 
Hole 390A, these new age assignments reveal that the age 
span of stable isotope and benthic foraminiferal abundance 
data generated by Friedrich and others (2004) and Friedrich 
and Hemleben (2007), respectively, was underestimated by 
over 3.5 m.y. These authors assigned samples between 
horizons 390A-14-5, 70 cm and -13-2, 53 cm (139.71- 
125.93 mbsf) to the lower Maastrichtian and assigned an 
age range from 71.3 to 69.6 Ma using the Gradstein and 
others (1994) time scale. Their age assignments were based 
on the assumptions that this stratigraphic interval corre- 
lates with the Globotruncana falsostuarti-Gansserina gans- 
seri Zone and that sedimentation was continuous and 
averaged 1.2 m/m.y. However, the revised age model for 
Hole 390A suggests (1) the oldest sample in their study 
correlates with the Radotruncana calcarata Zone and should 
be assigned an age of 74.56 Ma, (2) the youngest sample 
correlates with the Racemiguembelina fructicosa Zone and 
should be assigned an age of 69.33 Ma, (3) a 0.42-m.y. 
unconformity occurs at 139.36 Ma and marks the top of the 
K calcarata Zone, and (4) the sedimentation rate above the 
178 HUBER AND OTHERS 
>~; m 
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^530+        Warming 
Friedrich 
et al. (2004) 
age range 
Revised age for 
Friedrich et al. 
(2004) data 
? Nuttatlides truempyi    n Globigerinell. prairiehillensis 
? Gavel, beccariiformis   > Globigerinell. subcarinatus 
4 Mixed benthics o Bull</fine fraction carbonate 
+ Rugoglobigerina spp. 
o Heterohelix globulosa 
O Globotruncana area 
X Contusotruncana fornicata 
K Contusotruncana contusa 
X Globotruncanita stuartiformis 
Pseudoguem. palpebra 
Racemiguem. fructicosa 
FIGURE 9. Revised ages for previously published oxygen isotope data spanning the late Campanian-Maastrichtian from deep-sea sites drilled 
along the Blake Nose depth transect. Planktonic foraminiferal biozone abbreviations include ventric. = Globotruncana ventricosa Zone; ca. = 
Radotruncana calcarata Zone; palpebra = Pseudoguembelina palpebra Zone; mayaroensis = Ahathomphalus mayaroensis Zone; har. = 
Pseudoguembelina hariaensis Zone. Stable isotope data for Holes 1052E and 1050C from MacLeod and Huber (2001), MacLeod and others 
(2001) and Isaza-Londoiio and others (2006). Hole 390A stable isotope data from MacLeod and others (2000; mixed benthics: Globotruncana area, 
Heterohelix globulosa, Globigerinelloides subearinatus and Rugoglobigerina spp.) and Friedrich and others (2004: all other data). Upper inoceramid 
extinction level ("Ino.") identified by MacLeod and others (2000), lower extinction level (= *Ino.) by Friedrich and others (2007). See text for 
additional discussion. 
R. calcarata Zone averaged 2.49 m/m.y. Therefore, Frie- 
drich and Hemleben (2007) underestimate by over 3 mil- 
lion years the amount of time for major reorganization of 
deep- and intermediate-water circulation. Similarly, Frie- 
drich and Hemleben (2007) identified a major decline in 
inoceramid abundance at 134.5 mbsf, which is 8.63 m 
below the inoceramid extinction level observed by Mac- 
Leod and others (2000) in Hole 390A. According to the new 
age model, this inoceramid decline should be assigned an 
age of 72.6 Ma, which is 3 m.y. earlier than the age assigned 
by Friedrich and Hemleben (2007). Absence of upper 
Campanian sediments older than 71.62 Ma at Sites 1050 
and 1052 (Table 6) prevents an opportunity to test whether 
this inoceramid abundance change occurred at shallower 
depths on the Blake Nose. 
The inoceramid bivalve extinction event observed within 
the lowermost Ahathomphalus mayaroensis Zone in Holes 
1052E and 1050C (MacLeod and Huber, 2001) is now age 
dated between 68.5 and 68.7 Ma. This is in good agreement 
with the 68.6-68.9 Ma age for this extinction event reported 
by Frank and others (2005) at three sites on the Shatsky 
Rise. Published 6"*0 and 5"C data obtained from benthic 
and planktonic foraminifera and from bulk and fine- 
fraction carbonate do not show significant positive or 
negative shifts that correlate with the inoceramid extinction 
(Figs. 9, 10). Thus, the hypothesis that major shifts in 
source regions and circulation patterns for intermediate and 
deep water promoted the decline or extinction of the 
inoceramid bivalves (e.g., MacLeod, 1994; MacLeod and 
Huber, 1996; Frank and Arthur, 1999; MacLeod and 
others, 2000; Friedrich and others, 2004; Friedrich and 
Hemleben, 2007; Frank and others, 2005) is not supported 
by the combined results obtained from the Blake Nose. 
However, if the mid-Maastrichtian hiatus at Hole 390A and 
Site 1049 is coincident with and causally related to the 
slumps at 1050C and 1052E, it is possible that at the Blake 
BLAKE NOSE CHRONOSTRATIGRAPHY 179 
Hole1052E Hole1050C Hole390A 
d^^c 513c 
0.0       1.0       2.0       3.0 
^       Deccan 
Warming 
Friedrich 
et al. (2004) 
age range 
Revised age for 
Friedrich et al. 
(2004) data 
o ow- 
? Nuitallides tmempyi    ? Globigerinell. prairiehillensis   + Rugoglobigehna spp.    x 
? Gavel, beccariiformis   > Globigerinell. subcahnatus     o Heterolielix globulosa   ? 
4 Mixed bentlnics ?  Bull</fine fraction carbonate    <> Globotruncana area      x 
FIGURE 10.    Revised ages for previously published carbon isotope data spanning the 
along the Blake Nose depth transect. See caption for Figure 8 and text for explanation. 
Contusotruncana fornicata , Pseudoguem. palpebra 
CorXusotruncana contusa . Racemiguem. fructicosa 
Globotruncanita stuartiformis 
late Campanian-Maastrichtian from deep-sea sites drilled 
TABLE  6.    Age   and  duration   (m.y.)   of upper  Campanian- 
Maastrichtian unconformities on the Blake Nose. 
Base 
(Ma) Top (Ma) Duration (m.y.) 
Hole 390A 
69.22 66.86 2.35 
75.04 74.62 0.42 
110.00 75.55 
Hole 1049C 
34.45 
68.85 66.94 1.91 
75.05 73.90 1.15 
110.00 75.57 
Hole 1050C 
34.43 
65.56 65.50 0.06 
67.44 66.78 0.66 
75.04 71.62 3.42 
87.30 77.10 
Hole 1052E 
10.20 
65.78 65.50 0.23 
67.52 66.49 1.03 
69.34 68.82 0.52 
96.80 71.04 25.76 
Nose the manifestation of changing circulation patterns is 
sedimentological and not evidenced by isotopic changes. 
The updated stable isotope plots for Holes 1052E and 
1050 support the claim (Wilf and others, 2003) that a 0.6 to 
0.8%o negative shift in benthic and planktonic foraminiferal 
8"*0 values (~3?C warming) between 65.90 and 65.65 Ma. 
(Fig. 9) was synchronous with the onset of Deccan 
volcanism, which began at the base of Chron C29R 
(Courtillot and others, 1986; Hansen and others, 1996). 
This oxygen isotopic warming event has not been observed 
at Site 390 because published stable isotope data terminate 
below this time interval. 
CONCLUSIONS 
Age-depth models are created for the upper Campanian- 
Maastrichtian interval recovered from DSDP/ODP Holes 
390A/1049C and ODP Holes 1050C and 1052E, which were 
drilled along a middle to upper bathyal depth transect on 
the Blake Nose in the subtropical North Atlantic Ocean. 
These age models are constructed using published and 
reinterpreted magneto-, chemo-, and biostratigraphic da- 
tums along with new biostratigraphic observations, all of 
180 HUBER AND OTHERS 
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Ci. ^ ^ ><; 1 =<5 
1 
1 5 ?^ 2 a c .^ .^ Q S S -Ci   a 
'2 C ^ i "3 
5 "1 .? II 
i Q -Cl ? .Q a ^ 
^ ^ 1 ? c 1 1 3 II C ^3 a c s s; 
1 i 1 o '2 o g 1 u g ^ B 3 1 g 1 S Q c s 1 ^ s> a g ^??-? 
3 e i c! e =5 H e ^ =5.5 <5 
which are age calibrated using the Gradstein and others 
(2004) geomagnetic time scale. The revised age models 
enable greater accuracy in chronostratigraphic correlation, 
characterization of changes in sedimentation rates, and 
determination of the stratigraphic position, timing, and 
duration of unconformities. These refinements provide a 
much more reliable framework for interpretation of biotic 
and paleoceanographic changes that occurred during the 
last 10 m.y. of the Cretaceous Period as observed on the 
Blake Nose. 
The relative order and timing of a majority of the 
planktonic foraminiferal and calcareous nannofossil datum 
events identified at the Blake Nose sites show very good 
agreement among sites. Exceptions among the planktonic 
foraminifera include the zonal marker species Globotrun- 
cana aegyptiaca and Gansserina gansseri, which both have 
rare and sporadic distributions at the Blake Nose drill sites. 
Because recognition of the G. gansseri and G. aegyptiaca 
Zones is deemed unreliable, we define a new Pseudoguem- 
belina palpebra Interval Zone for biostratigraphic subdivi- 
sion between the Globotruncanella havanensis Partial-range 
Zone and the Racemiguembelina fructicosa Partial-range 
Zone. The FAD of P. palpebra is calibrated as 71.64 Ma. 
Secondary planktonic foraminiferal datum ages that are 
estimated from mean values obtained from the Blake Nose 
age models include: (1) the LAD of Gansserina gansseri = 
65.93 Ma, (2) the LAD of Contusotruncana patelliformis = 
66.20, (3) the LAD of Globotruncana linneiana = (fl.Zd Ma, 
(4) the LAD of Globotruncana bulloides = 68.80 Ma, (5) the 
LAD of Contusotruncana fornicata = 68.98 Ma, (6) the 
FAD of Pseudotextularia elegans = 69.02 Ma, (7) the FAD 
of Planoglobulina acervulinoides = 69.55 Ma, (8) the FAD 
of Contusotruncana contusa = 70.5 Ma, (9) the FAD of 
Pseudoguembelina kempensis = 71.50 Ma, (10) the FAD of 
Racemiguembelina powelli = 70.98 Ma and (11) the FAD of 
Pseudoguembelina excolata = 74.40 Ma. 
Revision of the late Campanian-Maastrichtian chronol- 
ogy for the Blake Nose sites has an important bearing on 
paleoceanographic interpretations that have been made 
based on data generated from the drill cores and in 
correlation with data from other regions. Of particular 
interest is determination whether reorganization of the 
sources and patterns of deep- and intermediate-water 
circulation played a role in biotic changes, particularly the 
extinction of inoceramid bivalves. The extinction of 
inoceramid bivalves is now dated between 68.5 and 
68.7 Ma on the Blake Nose. Combined stable isotope 
datasets published for the Blake Nose sites do not show any 
significant change in foraminiferal, bulk- and fine-fraction- 
carbonate 5"*0 and 6'^C values in this interval. 
The new chronology also provides reliable constraints on 
the timing and duration of Late Cretaceous unconformities 
across the Blake Nose transect. A mid-Maastrichtian 
unconformity with a duration ranging between 0.7 and 
1.9 m.y. is identified at all three sites across the 1300-m- 
depth transect. Several additional unconformities occur 
within the upper Campanian, and the oldest of these spans 
the period from 10.2 to 34.4 m.y. The more precise age 
dating of these unconformities will provide a framework for 
understanding their cause and regional to global extent. 
BLAKE NOSE CHRONOSTRATIGRAPHY 181 
ACKNOWLEDGMENTS 
This research used samples and data provided by the 
Integrated Ocean Drilling Program (lODP). lODP is 
sponsored by the U. S. National Science Foundation 
(NSF) and participating countries under management of 
the Joint Oceanographic Institutions (JOl), Inc. We extend 
our thanks to Jean Self-Trail (U. S. Geological Survey) for 
providing unpublished calcareous nannofossil biostrati- 
graphic data and for training BTH in identification of 
some Maastrichtian species; Jim Ogg (Purdue University) 
for advice on correlation between Cretaceous biostrati- 
graphic datums and the 2004 geomagnetic time scale; John 
McArthur for permission to use LOWESS version 4B; and 
to the CHRONOS System for developing and providing 
onHne access to the Age-depth Profile tool. This study 
benefited from reviews by R. K. Olsson and an anonymous 
reviewer and editorial suggestions by C. Brunner and M. R. 
Petrizzo. 
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