The Alaska Range suture zone exposes Cretaceous to Quaternary marine
and nonmarine sedimentary and volcanic rocks sandwiched between oceanic
rocks of the accreted Wrangellia composite terrane to the south and older
continental terranes to the north. New U-Pb zircon ages, 40Ar/39Ar, ZHe, and
AFT cooling ages, geochemical compositions, and geological field observations
from these rocks provide improved constraints on the timing of Cretaceous to
Miocene magmatism, sedimentation, and deformation within the collisional
suture zone. Our results bear on the unclear displacement history of the seismically
active Denali fault, which bisects the suture zone. Newly identified
tuffs north of the Denali fault in sedimentary strata of the Cantwell Formation
yield ca. 72 to ca. 68 Ma U-Pb zircon ages. Lavas sampled south of the Denali
fault yield ca. 69 Ma 40Ar/39Ar ages and geochemical compositions typical of
arc assemblages, ranging from basalt-andesite-trachyte, relatively high-K, and
high concentrations of incompatible elements attributed to slab contribution
(e.g., high Cs, Ba, and Th). The Late Cretaceous lavas and bentonites, together
with regionally extensive coeval calc-alkaline plutons, record arc magmatism
during contractional deformation and metamorphism within the suture zone.
Latest Cretaceous volcanic and sedimentary strata are locally overlain by
Eocene Teklanika Formation volcanic rocks with geochemical compositions
transitional between arc and intraplate affinity. New detrital-zircon data from
the modern Teklanika River indicate peak Teklanika volcanism at ca. 57 Ma,
which is also reflected in zircon Pb loss in Cantwell Formation bentonites.
Teklanika Formation volcanism may reflect hypothesized slab break-off and
a Paleocene–Eocene period of a transform margin configuration. Mafic dike
swarms were emplaced along the Denali fault from ca. 38 to ca. 25 Ma based
on new 40Ar/39Ar ages. Diking along the Denali fault may have been localized
by strike-slip extension following a change in direction of the subducting
oceanic plate beneath southern Alaska from N-NE to NW at ca. 46–40 Ma.
Diking represents the last recorded episode of significant magmatism in the
central and eastern Alaska Range, including along the Denali fault. Two tectonic
models may explain emplacement of more primitive and less extensive Eocene–Oligocene magmas: delamination of the Late Cretaceous–Paleocene
arc root and/or thickened suture zone lithosphere, or a slab window created
during possible Paleocene slab break-off. Fluvial strata exposed just south
of the Denali fault in the central Alaska Range record synorogenic sedimentation
coeval with diking and inferred strike-slip displacement. Deposition
occurred ca. 29 Ma based on palynomorphs and the youngest detrital zircons.
U-Pb detrital-zircon geochronology and clast compositional data indicate the
fluvial strata were derived from sedimentary and igneous bedrock presently
exposed within the Alaska Range, including Cretaceous sources presently
exposed on the opposite (north) side of the fault. The provenance data may
indicate ~150 km or more of dextral offset of the ca. 29 Ma strata from inferred
sediment sources, but different amounts of slip are feasible.
Together, the dike swarms and fluvial strata are interpreted to record Oligocene
strike-slip movement along the Denali fault system, coeval with strike-slip
basin development along other segments of the fault. Diking and sedimentation
occurred just prior to the onset of rapid and persistent exhumation
ca. 25 Ma across the Alaska Range. This phase of reactivation of the suture
zone is interpreted to reflect the translation along and convergence of southern
Alaska across the Denali fault driven by highly coupled flat-slab subduction of
the Yakutat microplate, which continues to accrete to the southern margin of
Alaska. Furthermore, a change in Pacific plate direction and velocity at ca. 25 Ma
created a more convergent regime along the apex of the Denali fault curve, likely
contributing to the shutting off of near-fault extension- facilitated arc magmatism
along this section of the fault system and increased exhumation rates.
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This content will become publicly available on November 22, 2024
Source‐to‐sink tandem geochronology reveals tectonic influences on the Cambrian Transcontinental Arch of Laurentia
Competing hypotheses attribute the regional loss of 1.2–1.0 Ga detrital zircon from the Cambrian Sauk Sequence in southwestern North America to differing tectonic controls on surface topography. We test three hypotheses with source‐to‐sink detrital zircon provenance analysis via tandem in situ and isotope dilution U–Pb geochronology paired with geochemical and Hf‐isotope tracers. Our data indicate that the lower‐to‐middle Sixtymile Formation in Grand Canyon was derived from ca. 1.1 Ga rocks of the Llano Uplift and the ca. 539–523 Ma Wichita igneous province, approximately 1400 km away. In contrast, new U–Pb geochronology links the upper Sixtymile and Tapeats formations to the 513–510 Ma Florida Mountains intrusive complex, southern New Mexico, and proximal 1.4 and 1.7 Ga basement approximately 650 km away. We attribute a regional provenance shift to plume–lithosphere interactions on the Iapetan margin, tectonism along ‘leaky’ intracratonic transverse fault zones and the rift‐to‐drift transition on the Cordilleran margin.
more » « less- NSF-PAR ID:
- 10494473
- Publisher / Repository:
- Wiley-Blackwell
- Date Published:
- Journal Name:
- Terra Nova
- Volume:
- 36
- Issue:
- 2
- ISSN:
- 0954-4879
- Format(s):
- Medium: X Size: p. 161-169
- Size(s):
- ["p. 161-169"]
- Sponsoring Org:
- National Science Foundation
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