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Provenance analysis of the Dezadeash Formation (Jura-Cretaceous), Yukon, Canada: Implications regarding a
linkage between the Wrangellia composite terrane and the western margin of Laurasia
Journal: Canadian Journal of Earth Sciences
Manuscript ID cjes-2017-0244.R2
Manuscript Type: Article
Date Submitted by the Author: 05-Sep-2018
Complete List of Authors: Lowey, Grant; Pilot Mountain
Keyword: Provenance, geochemistry, petrography, Dezadeash, Wrangellia
Is the invited manuscript for consideration in a Special
Issue? :Not applicable (regular submission)
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10 Provenance analysis of the Dezadeash Formation (Jura-Cretaceous), Yukon, Canada:
11 Implications regarding a linkage between the Wrangellia composite terrane
12 and the western margin of Laurasia
1314151617181920 Grant W. Lowey
21
22
23
24 P.O. Box 21254
25 Whitehorse, Yukon, Canada, Y1A 6R2
26 (E-mail: loweygrant@gmail.com)
27
28
29
30 Keywords Provenance, geochemistry, petrography, Dezadeash, Wrangellia, turbidite
31
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32 Abstract: The Mesozoic convergence of the allochthonous Wrangellia composite terrane
33 (WCT) with the western margin of Laurasia coincided with the construction of the Chitina
34 magmatic arc on the WCT, and the dispersal of volcanic flows and sediment gravity flows
35 into an adjacent flysch basin. The basin, preserved as the Gravina-Nutzotin belt, includes
36 the Dezadeash Formation in southwest Yukon, the Nutzotin Mountains sequence in
37 southern Alaska, and the Gravina belt in southeastern Alaska. The Dezadeash Formation is
38 a submarine fan system comprising stacked channel-lobe transition and lobe deposits
39 interposed with overbank deposits. Conglomerate pebble-counts, sandstone point-counts,
40 detrital zircon ages, and major element, trace element, rare earth element, and Sm-Nd
41 isotopic geochemistry of sandstone, mudstone, and hemipelagite beds suggests that the
42 deposits consist mainly of first-cycle volcanogenic detritus shed from the undissected
43 Chitina arc, in addition to material eroded from the WCT. The arc was constructed of
44 undifferentiated magma sourced from the depleted mantel, as well as older crustal material
45 attributed to the WCT proxying for continental crust. The compositional provenance
46 results, together with published paleocurrent data for the Dezadeash Formation and
47 compositional and directional provenance indicators from the Nutzotin Mountains sequence
48 and Gravina belt, does not require a sediment source from Laurasia. The provenance record
49 is compatible with deposition of the Gravina-Nutzotin belt in a convergent plate margin
50 setting.
51
52 Introduction
53 The Dezadeash Formation is part of the Gravina-Nutzotin belt (Berg et al., 1972),
54 an assemblage of Late Jurassic to Early Cretaceous volcanolithic turbidites up to 3000 m
55 thick with locally important interbedded conglomerate and volcanic rocks, that extends
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56 from southeastern Alaska, through southwestern Yukon, and into southern Alaska. It is
57 subdivided from south to north, into the Gravina belt, Dezadeash Formation, and Nutzotin
58 Mountains sequence (Fig.1). These assemblages are interpreted as submarine fan deposits
59 and submarine volcanic flows that unconformably overly the eastern margin of the
60 allochthonous Wrangellia composite terrane (WCT, ~Insular superterrane, Monger, 2014),
61 a microcontinent assembled in the paleo-Pacific Ocean (Beranek et al., 2014). The
62 Dezadeash Formation and Nutzotin Mountains sequence are interpreted as the same
63 stratigraphic unit that was dismembered and displaced ~370 km by the Denali fault system
64 (Eisbacher, 1976; Lowey, 1998); their geographic continuity with the Gravina belt is
65 uncertain, but all three assemblages were likely deposited in the same overall tectonic
66 setting (Berg et al., 1972). However, the tectonic setting is controversial due to
67 uncertainties regarding the timing and location of collision of the WCT with Laurasia
68 (McCelland et al., 1992; Monger et al., 1994), the number of volcanic arcs present and their
69 polarity (Nokleberg and Richter, 2007; Gehrels et al., 2009), and whether the margin of
70 Laurasia contributed sediment to the Gravina-Nutzotin belt (Berg et al., 1972; Nokleberg et
71 al., 1985; Kapp and Gehrels, 1998; McClelland and Mattinson, 2000).
72 A compositional provenance link between the Gravina-Nutzotin belt and Laurasia
73 was proposed by Kapp and Gehrels (1998) who concluded that 380-310 and >900 Ma
74 detrital zircons from the Gravina belt were sourced from the continental margin of Laurasia
75 (i.e., Yukon-Tanana and Stikine terranes, Fig. 1). However, Hults et al. (2013) argued that
76 zircons of this age were derived from the WCT, and Yokelson et al. (2015) proposed that
77 detrital zircons from the 'western' Gravina belt were also sourced from the west (i.e., the
78 WCT). A compositional provenance link between the Gravina-Nutzotin belt and Laurasia
79 was also proposed by Berg et al. (1972) and Richter (1976) who suggested that clasts of
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80 white vein quartz and metamorphic rocks from the Nutzotin Mountains sequence were
81 derived from Laurasia (i.e., Yukon-Tanana terrane). These observations though, were based
82 on regional mapping over 40 years ago and additional mapping (e.g., Dodds and Campbell,
83 1992), together with sedimentological studies incorporating paleocurrent measurements
84 (e.g., Eisbacher, 1976; Kozinski, 1985; Lowey, 1980, 1998; Cohen, 1992; Manuszak,
85 2000), have cast doubt on a Laurasian source for the clasts. Furthermore, Manuszak et al.
86 (2007) concluded that their study was unable to establish a direct unequivocal provenance
87 link between the Nutzotin Mountains sequence and Laurasia.
88 The Dezadeash Formation is presently located further east than the Nutzotin
89 Mountains sequence, implying that it may have been closer to Laurasia and therefore more
90 likely to contain a record of sediment derived from the continental margin. On account of
91 the potential limitations of provenance analysis, such as non-unique sediment sources,
92 internal variability within a single source area, incomplete characterization of potential
93 sources, sediment recycling, climatic and erosion effects, grain attrition during transport,
94 hydraulic sorting, and post-depositional alteration (Rollinson, 1993; McLennan et al., 2003;
95 Nie et al., 2012), this paper presents the results of an integrated provenance analysis of the
96 Dezadeash Formation, including pebble-counts of conglomerate beds, radiometric and
97 fossil dating of conglomerate clasts, grain point-counts of thin sections of sandstones, U-Pb
98 dating of detrital zircons from sandstones, and whole-rock geochemisty of sandstone,
99 mudstone, and hemipelagite beds, including major elements, trace elements, rare earth
100 elements, and Sm-Nd isotopes. Paleocurrent data from the Gravina-Nutzotin belt are also
101 reviewed. The primary aim is to characterize the lithological and geochemical composition
102 of the Dezadeash Formation, thereby facilitating comparisons with other Jura-Cretaceous
103 flysch basins exposed along the western margin of North America. Secondary aims are to
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104 use the new compositional dataset to constrain the provenance and tectonic setting of the
105 Dezadeash Formation.
106
107 Geologic Setting
108 The WCT (Fig. 1) is a composite block of three amalgamated tectonostratigraphic
109 terranes referred to as the Alexander, Wrangellia, and Peninsular terranes (Plafker and
110 Berg, 1994). The Alexander terrane includes a basement of Neoproterozoic to early
111 Paleozoic island arc-related volcanic and sedimentary rocks (Nokleberg et al., 1994;
112 Beranek et al., 2012), and also late Paleozoic island arc-related volcanic and sedimentary
113 rocks. The Wrangellia terrane consists mainly of late Paleozoic to early Mesozoic island
114 arc-related volcanic and sedimentary rocks. The Peninsular terrane consists of an
115 assemblage of Mesozoic arc-related volcanic rocks (Nokleberg et al., 1994). The three
116 terranes represent successively higher structural and stratigraphic successions from
117 southeast to northwest (Nokleberg et al., 1994). The Alexander and Wrangellia terranes
118 were contiguous during late Paleozoic time, based on Pennsylvanian-age plutons that
119 intrude both terranes (Gardner et al., 1988). The Peninsular terrane is interpreted to have
120 collided in Late Jurassic time with either the western margin of Laurasia (the Yukon
121 composite terrane), or the combined Alexander-Wrangellia terrane (Clift et al., 2005;
122 Beranek et al., 2014). The WCT, interpreted as part of an obliquely converging oceanic
123 plateau (Greene et al., 2010), was emplaced against the margin of Laurasia during Middle
124 Jurassic to mid-Cretaceous time (Monger et al., 1982; McClelland et al., 1992; Nokleberg
125 et al., 1994).
126 The Yukon composite terrane (YTC, ~Intermontane superterrane, Monger, 2014)
127 (Fig. 1) refers to the polymetamorphosed and polydeformed Yukon-Tanana, Slide
128 Mountain, Cache Creek, Quesnellia, and Stikinia terranes (Wheeler and McFeely, 1991;
129 Monger, 2014). The YTC includes a substrate of Proterozoic to Paleozoic metasedimentary
130 and mafic meta-igneous rocks, overlain by an assemblage of Devonian-Mississippian arc-
131 related volcanic and sedimentary rocks (Plafker and Berg, 1994; Nelson et al., 2013). The
132 YTC was rifted from the ancient margin of North America in middle Paleozoic time,
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133 resulting in the formation of the oceanic Slide Mountain terrane, and subsequently re-
134 attached to North America in the latest Paleozoic (Nelson et al., 2013). The Cache Creek
135 terrane is a subduction-related assemblage that is flanked by late Paleozoic to early
136 Mesozoic volcanic arc rocks belonging to Quesnellia and Stikinia (Goldfarb et al., 2013;
137 Monger, 2014). Final accretion of the YTC to the western margin of Laurentia occurred in
138 mid-Jurassic to Cretaceous time (Monger et al., 1982; Monger and Journeay, 1994; Nelson
139 et al., 2013).
140 Several Mesozoic magmatic arcs, termed the Talkeetna (~205-155 Ma; Onstott et
141 al., 1989; Palfy et al., 1999; Rioux et al., 2003, 2007), Chitina (~160-140 Ma; Plafker et al.,
142 1989; Nokleberg et al., 1994; Roeske et al., 1991, 2003), and Chisana (~130-110 Ma; Short
143 et al, 2005; Snyder et al., 2005) erupted across the WCT from west to east. The Chitina arc
144 occurs between the Talkeetna and Chisana arcs in both time and space. Volcanic rocks of
145 the Chitina arc are preserved in the Gravina belt, but not in the Nutzotin Mountains
146 sequence or Dezadeash Formation, although volcaniclastic rocks occur in the Dezadeash
147 Formation. The volcaniclastic rocks in the Dezadeash Formation consist of fine-to medium-
148 grained vitric to crystal tuffs interpreted as resedimented syn-eruptive volcaniclastic gravity
149 flow deposits (Lowey, 2011). A U-Pb zircon age (149.4 + 0.3 Ma) indicates the
150 volcaniclastic rocks are contemporaneous with the Chitina arc, and Sm-Nd systematics
151 suggest the volcaniclastic rocks represent mixing of a depleted mantle source and an older
152 crustal source (Lowey, 2011). Furthermore, a variety of tectonic discriminant diagrams
153 show the volcaniclastic rocks have a continental arc signature, which Lowey (2011)
154 attributed to the WCT proxying for continental crust.
155 The Gravina-Nutzotin belt (Fig. 1) depositionally overlies the Alexander and
156 Wrangellia terranes (Jones et al., 1982). It consists of the Dezadeash Formation located
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157 near the middle of the belt, the Nutzotin Mountains sequence at the northern end of the belt,
158 and the Gravina belt at the southern end of the belt (Fig. 2). The Dezadeash Formation is
159 approximately 3000 m thick and consists of thin- to thick-bedded turbidites and massive
160 sandstone with minor amounts of conglomerate (containing limestone clasts up to ~10 m in
161 exposed longest dimensions), volcaniclastic rocks, and hemipelagic lime mudstone
162 (Eisbacher, 1976; Lowey, 1992, 2007). The strata are unmetamorphosed to regionally
163 metamorphosed up to subgreenschist facies (laumontite-prehnite-quartz; Dodds and
164 Campbell, 1992). The Dezadeash Formation is Late Jurassic (Oxfordian) to Early
165 Cretaceous (Valanginian) in age based on collections of the bivalve Buchia (Eisbacher,
166 1976), and unnconformably overlies the Wrangellia terrane, specifically Triassic volcanic,
167 volcaniclastic, and carbonate rocks belonging to the Nikolai Formation, McCarthy
168 Formation, and Chitistone and Nisina Limestone (Dodds and Campbell, 1992). Based on
169 detailed lithofacies analysis, the Dezadeash Formation represents mainly the middle and
170 lower subdivisions of a point-source, mud/sand-rich submarine fan (Lowey, 2007) that was
171 derived from the west (Eisbacher, 1976). The Dezadeash Formation is overlain
172 unconformably by Paleogene clastic and volcaniclastic rocks of the Amphitheater
173 Formation (Eisbacher, 1976). Immediately east of the Dezadeash Formation is the Kluane
174 Schist (Fig. 1), a 160 km long belt of mainly mica-quartz schist of uncertain age and origin.
175 Eisbacher (1976) proposed that the Kluane Schist represents the higher grade
176 metamorphosed Dezadeash Formation, but zircon geochronology by Stanley (2012)
177 suggests that the protolith of the Kluane Schist may be younger (i.e., Late Cretaceous) than
178 the Dezadeash Formation.
179 The Nutzotin Mountains sequence (Fig. 2) is up to 3000 m thick and consists
180 mainly of low-grade metamorphosed thin-bedded turbidites with minor amounts of massive
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181 sandstone, matrix-supported conglomerate (containing limestone clasts up to ~10 m in
182 exposed longest dimensions), and hemipelagite beds (Berg et al., 1972; Richter, 1976;
183 Kozinski, 1985; Manuszak et al., 2007). The strata are Late Jurassic (Tithonian) to Early
184 Cretaceous (Valanginian) in age based on the bivalve Buchia, and unconformably overlies
185 the Wrangellia terrane (Manuszak and Ridgway, 2000). The Nutzotin Mountains sequence
186 is interpreted as westerly sourced, distal to proximal submarine fan deposits that grade
187 upward into shelf deposits (Kozinski, 1985; Manuszak et al., 2007). The Nutzotin
188 Mountains sequence is conformably overlain by the Chisana Formation, a ~3000 m thick
189 assemblage of volcanic-lithic breccia, basaltic-andesite flows, volcaniclastic rocks, and
190 mudstone (Berg et al., 1972; Richter, 1976; Barker, 1987). The Chisana Formation is
191 interpreted to have been deposited proximal to volcanic vents on subaqueous slopes of the
192 contemporaneous proto-continental, or intraoceanic Chisana arc (Short et al., 2005).
193 Eisbacher (1976) proposed that the Dezadeash Formation and Nutzotin Mountains
194 sequence represent the same strata that were dismembered and displaced by the Denali fault
195 system (Eisbacher, 1976). The Denali fault system is one of the main transcurrent faults in
196 the northern part of the North American Cordillera, along which ~370 km of dextral slip
197 occurred since the Early Cretaceous (Clague, 1979; Lowey, 1998, and references therein).
198 Sedimentologic and stratigraphic studies by Kozinski (1985), Manuszak (2000), and
199 Manuszak and Ridgway (2000) on the Nutzotin Mountains sequence corroborates this
200 interpretation.
201 The Gravina belt comprises the Seymour Canal Formation (Fig.2), Douglas Island
202 Volcanics and Brothers Volcanics, and the Treadwell Formation (Gehrels, 2000). The
203 Seymor Canal Formation is ~1800 m thick and consists of sandstone and mudstone
204 turbidites with minor amounts of conglomerate, volcanic rocks, and volcaniclastic rocks
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205 (McClelland et al., 1991; Cohen, 1992; Gehrels, 2000). Strata are regionally
206 metamorphosed to zeolite, prehnite-pumpellyite, and lower-greenschist facies in the north,
207 increasing to greenschist facies in the south (Cohen and Lundberg, 1993). The Seymour
208 Canal Formation is Late Jurassic (Oxfordian) to Early Cretaceous (Albian) in age and
209 unconformably overlies the Alexander terrane (Cohen, 1992; Cohen and Lundberg, 1992).
210 The strata are interpreted as upper and middle submarine fan sediments sourced from the
211 west (Cohen, 1992; Gehrels, 2000). The Seymor Canal Formation is conformably overlain
212 by basalt breccia and pillowed volcanic flows of the Douglas Island Volcanics and Brothers
213 Volcanics, which are conformably overlain by sandstone, mudstone, and conglomerate
214 beds assigned to the Treadwell Formation (Gehrels, 2000). The Douglas Island Volcanics,
215 Brothers Volcanics, and Treadwell Formation are related to the Cretaceous Chisana arc
216 (Gehrels, 2000).
217 Near the southernmost part of the Gravina belt, an assemblage of greenschist to
218 amphibolite facies phyllite, schist, and metaconglomerate originally interpreted as part of
219 the Taku terrane was reinterpreted by Rubin and Saleeby (1991) as part of the Gravina belt
220 and named the 'Gravina sequence'. Since the tectonic affinity of these rocks is the subject of
221 a recent debate (Lowey, 2017) they are not considered further.
222
223 Methods
224 This study is based on 16,335 m of measured strata from 75 sections throughout the
225 Dezadeash Formation (Fig. 3, Supplementary Table S1). Approximately 200 samples
226 representative of the various lithofacies present were collected from these sections (Table
227 1). According to Lowey (2007), the lithofacies display no apparent overall vertical trend in
228 depositional architecture, interpreted as laterally and vertically repetitive submarine fan
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229 channel-lobe transition and lobe deposits separated by overbank deposits (Lowey, 2007),
230 and a subset of samples from the 200 initially collected were selected for analysis.
231 Conglomerate pebble-counts were performed on poorly sorted or disorganized
232 gravelly mudstone beds (Fig. 4A). The beds range from 3 to 23 m in thickness, and only
233 three conglomerate pebble-counts were undertaken due to the scarcity of conglomerate in
234 the Dezadeash Formation (~1.3 % of all lithofacies, based on the vertical percentage of
235 strata in all measured sections; Lowey, 2007). The pebble-counts consisted of identifying
236 the lithology of at least 100 clasts >1 cm long in a conglomerate bed that was encountered
237 during measuring a section. In addition to the pebble-counts, conglomerate clasts were
238 collected for K-Ar age determination and microfossil analysis. One diorite pebble was
239 selected for hornblende K-Ar age determination. The analysis was performed at Geochron
240 Laboratories, Chelmsford, Massachusetts. The sample was crushed and the -80/+200 mesh
241 fraction was used for mineral separation. Hornblende concentrate was separated by heavy
242 liquids, followed by washing with dilute HF and then HNO3 . K was analyzed by replicate
243 atomic absorption spectrophotometric methods, and Ar was analyzed by standard isotopic
244 dilution techniques using an 38Ar-enriched spike. Standard calibration methods were used
245 for the 38Ar tracer, and inter-laboratory standards were checked on a routine basis for both
246 K and Ar determinations. One limestone clast was selected for conodont analysis and
247 separated using standard acetic acid processing techniques by the Geological Survey of
248 Canada, Vancouver, British Columbia. A discussion of the procedure is provided by Harris
249 and Sweet (1989) and Orchard and Foster (1991).
250 Thirty samples of medium-grained sandstone, including thick- to medium-bedded
251 sandstone (Fig. 4B) and the sandstone portion of very thick- to thick-bedded sandstone-
252 mudstone couplets (Fig. 4C) were selected for point-count analysis. Standard thin sections,
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253 half of which were impregnated with blue epoxy, and standard off-cuts, all of which were
254 stained for potassium feldspars, were prepared by Vancouver Petrographics Ltd., Langley,
255 British Columbia. The thin sections were examined by transmitted light microscopy with a
256 petrographic microscope. Between 300-400 framework grains were identified in each thin
257 section using a modified Gazzi-Dickinson method (Dickinson, 1985). The Gazzi-Dickinson
258 method was modified such that sedimentary chert grains and sedimentary carbonate grains
259 were counted as framework lithic fragments due to their potential importance in
260 determining provenance (Zuffa, 1980; Mack, 1984). The sedimentary chert grains generally
261 account for <3% of the framework mode and sedimentary carbonate grains generally
262 represent <4% of the framework mode, and so their inclusion in the framework mode does
263 not significantly affect the position of sandstone compositions plotted on tectonic
264 discrimination diagrams of Dickinson and Suczek (1979). Matrix and cement were not
265 counted. In addition, 2 medium-grained sandstone samples (including one from thick- to
266 medium-bedded sandstone and one from the sandstone portion of very thick- to thick-
267 bedded sandstone-mudstone couplets), each weighing ~15 kg, were selected for U-Pb
268 isotopic analysis of detrital zircons. A total of ~200 detrital zircons were analyzed using
269 laser ablation-inductively coupled plasma-mass spectrometry (LA-ICP-MS) at the Arizona
270 LaserChron Center, Tucson, Arizona, utilizing methods described by Gehrels et al. (2008).
271 Isotope data and the weighted mean of the 207Pb/206Pb dates were calculated using the
272 program of Ludwig (2008).
273 A total of 41 samples were selected for whole rock geochemical analysis, including
274 29 sandstones (the sandstone matrix from disorganized conglomerate; the sandstone matrix
275 from pebbly sandstone; thick- to medium-bedded sandstone; and the sandstone portion of
276 very thick- to thick-bedded sandstone-mudstone couplets), seven mudstones (the mudstone
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277 portion of thin-bedded sandstone-mudstone couplets, Fig. 4D; thick siltstone-mudstone
278 laminae; and structureless mudstone), and five hemipelagite beds (lime mudstone, Fig. 4E).
279 Major element concentrations were determined by X-ray Fluorescence (XRF), trace
280 element and rare earth element (REE) abundances were measured by fusion inductively
281 coupled plasma-mass spectroscopy (ICP-MS), and Sc was analyzed by instrument neutron
282 activation analysis (INAA), at Activation Laboratories, Ancaster, Ontario. Analytical error
283 for the XRF method is <1% for major elements; for trace elements, precision is better than
284 6% and analytical error is better than 5%. Various trace-element diagrams were plotted
285 using the Igpet program by Carr (2000).
286 A total of 17 samples were selected for Sm-Nd isotopic analysis, including six
287 sandstones (the sandstone matrix from pebbly sandstones; thick- to medium-bedded
288 sandstone; and the sandstone portion of very thick- to thick-bedded sandstone-mudstone
289 couplets), five mudstones (the mudstone portion of thin-bedded sandstone-mudstone
290 couplets; and structureless mudstone), and six hemipelagite beds (lime mudstone). The Sm-
291 Nd isotopic analysis was performed on a Triton-MC mass-spectrometer by Activation
292 Laboratories, Ancaster, Ontario. Rock powder was dissolved in a mixture of HF, HNO3,
293 and HClO4, and before decomposition the sample was mixed with a 149Sm-146Nd spiked
294 solution. Sm and Nd were separated by extraction chromatography on HDEHP covered
295 Teflon powder. Total blanks are 0.1-0.2 ng for Sm and 0.1-0.5 ng for Nd. Accuracy of the
296 measurements of Sm and Nd are ±0.5% and 147Sm/144Nd ±0.5%. 143Nd/144Nd ratios are
297 relative to the value of 0.511860 for the La Jolla standard. During the work the weighted
298 average of 10 La Jolla Nd-standard runs yielded 0.511874±10 (2s) for 143Nd/144Nd, using
299 the depleted mantle value of 0.7219 for 146Nd/144Nd to normalize (Rollinson, 1993).
300
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301 Directional Provenance Indicators
302 Review
303 The most comprehensive directional provenance analysis of the Gravina-Nutzotin
304 belt was by Eisbacher (1976) who measured the orientation of >500 sole marks, cross
305 laminations, and slump folds throughout the Dezadeash Formation (Fig. 5). Eisbacher
306 (1976) corrected paleocurrent measurements for tectonic dip and plunge. Detailed mapping
307 and structural analysis did not reveal any potentially rotated fault blocks that may have
308 affected paleocurrent trends (Eisbacher, 1976). Eisbacher (1976) noted a weak fan-like
309 arrangement to the paleocurrent data and suggested that the overall paleoflow direction was
310 to the northeast. Based on the measurement of 24 sole marks and cross laminations
311 corrected for dip and plunge from the Dezadeash Formation, Lowey (1980) documented a
312 mean paleoflow direction to the northeast for stacked channel-lobe transition deposits and
313 lobe deposits, whereas overbank deposits displayed a mean paleoflow direction to the east.
314 The trend of a channelized debris flow deposit containing limestone clasts up to ~10 m in
315 exposed longest dimensions from the Dezadeash Formation was also determined to be to
316 the east (Lowey, 1998), although the direction was not corrected for dip and plunge because
317 the trend was determined from a ~2 km wide debris flow channel exposed on opposite side
318 of a mountain valley, and mapping by Dodds and Campbell (1992) did not show any
319 potentially rotated fault blocks.
320 In the southern part of the Nutzotin Mountains sequence, Koziski (1985)
321 documented northwest and northeast paleoflow directions based on the measurement of 212
322 cross laminations (Fig. 5); a northeast-southwest direction was recorded from a single sole
323 mark. Kozinski (1985) rotated bedding back to horizontal, but did not correct for plunge
324 because fold axes are approximately horizontal. According to Ramsey (1961), plunges less
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325 <25º can generally be ignored. In the middle part of the Nutzotin Mountains sequence
326 outcrop belt, Manuszak et al. (2007) determined a northeastward paleoflow direction based
327 on the measurement of 24 clast imbrications, whereas in the northern part of the belt, the
328 measurement of 89 clast imbrications indicated eastern and southeastern paleoflow
329 directions, and the measurement of 108 cross laminations revealed eastern sediment
330 dispersal (Manuszak et al., 2007). Manuszak et al. (2007) restored paleocurrent data to
331 horizontal based on bedding orientation. Structural analysis and mapping did not reveal any
332 potentially rotated fault blocks that may have affected paleocurrent trends (Manuszak et al.,
333 2007).
334 In the northern part of the Gravina belt, Cohen (1992) obtained only limited
335 paleocurrent data. A southwest and northwest paleoflow direction was determined from the
336 measurement of 28 cross laminations (Fig. 5), a southeast direction was based on the
337 orientation of five sole marks, and a northeast direction was obtained from the
338 measurement of five slump folds (Cohen, 1992). Cohen (1992) restored paleocurrents to
339 their original orientation and did not observe any rotated fault blocks that may have
340 affected paleocurrent trends.
341
342 Interpretations
343 The available paleocurrent indicators demonstrate consistent eastward-directed
344 sediment transport, suggesting that Gravina-Nutzotin belt strata was sourced from the west.
345 However, throughout the Gravina-Nutzotin belt imbricated clasts and cross laminations
346 tend to show a greater variance in paleocurrent directions compared to that of sole marks.
347 This may be attributed to the difficulty associated with obtaining accurate measurements
348 (only apparent directions of imbrication or cross lamination are measured unless
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349 exceptional, three-dimensional exposures exist; Potter and Pettijohn, 1977), turbulence or
350 variations in flow direction associated with a single turbidity current (Dzulynski and
351 Walton, 1965), and Coriolis forces deflecting overbank turbidity currents to the right
352 (looking down-channel) in the Northern Hemisphere (Wells and Cossu, 2013).
353 Furthermore, terranes in southern Alaska were likely rotated counterclockwise when
354 transported along arcuate faults such as the Denali fault system (Glen, 2004); reversing this
355 rotation brings paleocurrent orientations measured from the Nutzotin Mountains sequence
356 into closer alignment with those from the Dezadeash Formation.
357
358 Compositional Provenance Indicators
359 Pebble-count Analysis and Age of Conglomerate Clasts
360 Results
361 Raw pebble-count data is provided in Supplementary Table S2 and re-calculated
362 pebble-count data is summarized in Table 2. Conglomerates are characterized by a
363 dominance of volcanic and igneous mafic clasts (andesite, rhyolite, and gabbro). Other
364 clasts, in order of decreasing abundance, include limestone, diorite, chert, mudstone,
365 granite, and quartz. On the tectonic discriminant diagram of Cox and Lowe (1995), the
366 conglomerate compositions of the Dezadeash Formation plot in the mixed provenance and
367 volcanic arcs fields (Fig. 6A), whereas on the Plutonic-Volcanic-Sedimentary (P-V-S) clast
368 diagram by Dickie and Hein (1995), they plot in the arc flank field, or undissected arc (Fig.
369 6B). A hornblende K-Ar age of 144 ± 4 Ma was obtained from the diorite pebble (Table 3),
370 and based on conodonts, a Triassic (Late Norian) age was obtained from the limestone
371 cobble (Supplementary Table S3).
372
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373 Interpretations
374 Conglomerate clast compositions suggest derivation from a predominantly volcanic
375 source terrane with subordinate plutonic and sedimentary rocks, and minor vein quartz.
376 Conglomerate compositions plotted on the P-S-V tectonic discriminant diagram of Dickie
377 and Hein (1995) suggests an undissected arc provenance (Fig. 6B). Conglomerate
378 compositions from the Nutzotin Mountains sequence and Gravina belt overlap those of the
379 Dezadeash Formation, suggesting a similar tectonic setting.
380
381 Point-count Analysis
382 Results
383 Sandstone point-count parameters are summarized in Table 4. Raw point-count data
384 are provided in Supplementary Table S4 and re-calculated point-count data are shown in
385 Table 5. Although thick- to medium-bedded sandstones and the sandstone portion of very
386 thick- to thick-bedded sandstone-mudstone couplets were point-counted separately, there is
387 no significant difference between the detrital modes of these two lithofacies, and so they
388 are discussed as one group.
389 Sandstones are characterized by a dominance of lithic fragments (mainly volcanic)
390 compared to either quartz or feldspar (~Q12F26L62). Lithic fragments are dominated by
391 volcanic grains displaying mainly felsitic (Lvf) and lathwork (Lvl) textures. Minor amounts
392 of volcanic grains with microlitic textures (Lvm) are also present. Sedimentary lithic grains
393 are a minor component in the sandstones, and include chert (Lsc, with several grains
394 containing what appear to be radiolarian tests and spines infilled with microquartz),
395 limestone (Lsl, mainly lime micrite and recrystallized carbonate grains, with several
396 skeletal fragments of brachiopods, bryozoans and foraminifers), and mudstone (Lsm). Rare
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397 metamorphic lithic fragments of phyllite (Lmp) and schist (Lms) are also present. The ratio
398 of volcanic lithic grains to total lithic grains (Lv/L) ranges from 0.82 - 0.99, but is mostly >
399 0.90. Feldspar fragments are dominated by plagioclase grains (Fp) that display various
400 types of twinning, with Carlsbad+albite polysynthetic twinning the most common. The
401 plagioclase composition is consistently oligioclase (An19-21, based on the Michel-Levy
402 method). Potassium feldspar grains (Pk) are a minor component of the sandstones, and are
403 dominated by untwined orthoclase. Rare microcline grains displaying 'grid' or 'tartan'
404 twinning (i.e., combined albite+percline twinning) are also present. The ratio of plagioclase
405 to total feldspars (P/F) ranges from 0.68-1.00, but is mostly >0.80. Quartz fragments are
406 dominated by monocrystalline quartz grains (Qm) that are predominantly circular to
407 elliptical in shape, subangular to subrounded, and display non-undulose extinction. Rare
408 shard-like quartz grains and embayed quartz grains are also present. Polycrystalline quartz
409 grains (Qp) are a minor component of the sandstones, and consist mostly irregular-shaped
410 crystal aggregates in which individual crystals display undulose extinction and sutured
411 intercrystalline boundaries.
412 Other non-opaque grains not included in the point-counting (and accounting for
413 <1% of all grains) include clinopyroxene, orthopyroxene, hornblende, sphene, zircon,
414 biotite, and muscovite, in order of decreasing abundance. Opaque minerals were also
415 observed; they were also not included in the point-counting and also account for <1% of all
416 grains. The opaque minerals include magnetite, pyrite, limonite, and several orthopyroxene-
417 Fe-Ti oxide grains (magnetite and/or ilmenite ?) displaying symplectitic texture (a wormy,
418 irregular intergrowth; Barton and Gaans, 1988). Authigenic chlorite, sericite, laumontite,
419 natrolite, pumpellyite, prehnite, and irregular patches and veinlets of calcite are also
420 present.
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421 On the Qt-F-L tectonic discriminant diagram of Dickinson et al. (1983), sandstones
422 plot in the undissected arc and transitional arc fields (Fig.7A). On the Q-P-K tectonic
423 discriminant diagram of Dickinson and Suczek (1979), they plot in the magmatic arc field
424 (Fig.7B), whereas on the Qp-Ls-Lv diagram of Dickinson and Suczek (1979), they plot in
425 the arc orogen field (Fig. 8A); and on the Lm-Ls-Lv diagram Marsaglia and Ingersoll
426 (1992), they plot in the intraoceanic and continental arc fields (Fig. 8B).
427
428 Interpretations
429 Sandstone compositions plotted on the Qt-F-L discriminant diagram of Dickinson et
430 al. (1983) suggest an undissected to transitional arc (Fig. 7A); high ratios of P/F (~>0.8)
431 and Lv/L (~>0.9) favor an undissected arc (Ingersoll and Eastman, 2007). Sandstone
432 compositions plotted on the Lm-Ls-Lv tectonic discriminant diagram of Marsaglia and
433 Ingersoll (1992) suggest an intraoceanic to continental arc provenance (Fig. 8B). Marsaglia
434 and Ingersoll (1992) define a continental arc as one that has a basement of granitic rocks
435 and/or accreted terranes. Sandstone compositions from the Nutzotin Mountains sequence
436 and Gravina belt overlap those of the Dezadeash Formation (Figs. 7A, 7B, 8A, and 8B),
437 suggesting a similar tectonic setting.
438
439 Zircon Analysis
440 Results
441 Raw detrital zircon data are provided in Supplementary Table S5. Results of the analyses
442 are summarized in Pb/U concordia diagrams (Fig. 9) and in relative probability plots (Fig.
443 10). The separated zircons were generally colorless, euhedral prismatic crystals without
444 visible cores or zoning. Although detrital zircon ages range from ~ 2111-145 Ma (2112-148
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445 Ma for sample GL74A, and 2187-145 Ma for sample GL74B), only one grain is Paleozoic
446 in age and only five are Precambrian in age, resulting in a total distribution of 97%
447 Mesozoic, 0.5 % Paleozoic and 2.5% Precambrian ages (~M97 P0.5 Pc2.5). The detrital zircon
448 age data reveal concordant to slightly discordant Mesozoic age zircons, with the majority
449 between ~165-150 Ma, a dominant age mode at ~157 Ma, and subordinate age modes at
450 ~170, ~180 Ma and ~188 Ma. The maximum deposition age (MDA), determined by taking
451 the weighted mean age of three or more zircons that make up the youngest grain cluster
452 (Dickinson and Gehrels, 2009), is 148 Ma for sample GL74A and 147 Ma for sample
453 GL74B. Figure 11 provides a summary of detrital zircon data for the Dezadeash Formation
454 compared to other strata from the Gravina-Nutzotin belt and terranes in the Northern
455 Cordillera.
456
457 Interpretations
458 Calculated MDAs for the Dezadeash Formation are close to the ~149 Ma U-Pb
459 zircon age from a resedimented syn-eruptive tuff in the Dezadeash Formation (Lowey,
460 2011), and support the interpretation based on marine fossils that the Dezadeash Formation
461 is Late Jurassic (Oxfordian) to Early Cretaceous (Valanginian) in age (Eisbacher, 1976).
462 The detrital zircon age spectra of the Dezadeash Formation is dominated by Late Jurassic
463 grains (dominant age mode ~157 Ma), consistent with a source from an active volcanic arc,
464 most likely the Chitina arc (active ~160-140 Ma, Plafker et al., 1989; Roeske et al., 2003).
465 The detrital zircon age spectra from the Dezadeash Formation is similar to that
466 reported from the Nutzotin Mountains sequence (Manuszak et al., 2007; Hults et al, 2013)
467 and Gravina Belt (Kapp and Gehrels, 1998; Yokelson et al., 2015). Based on one sample
468 from the Nutzotin Mountains sequence, Hults et al. (2013) reported that detrital zircon ages
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469 range from 1539-132 Ma, with a dominant age mode between 170-140 Ma, a subordinate
470 age mode between 451-384 Ma, and several Precambrian grains, with an average
471 distribution of detrital zircon ages of ~M92 P6 Pc2; and based on one sample from the
472 Nutzotin Mountains sequence, Manuszak et al. (2007) reported that detrital zircon ages
473 range from 177-136 Ma, with a dominant age mode between 150-145 Ma, a subordinate
474 age mode between 176-164 Ma, and an average distribution of detrital zircon ages of ~M100
475 P0 Pc0. Yokelson et al. (2015) reported detrital zircon age spectra from seven samples of the
476 Gravina belt that were combined with results from five samples previously reported by
477 Kapp and Gehrels (1998). In the lowermost strata of the Gravina belt (specifically the base
478 of the Seymour Canal Formation), 'Fanshaw' samples contain a dominant age mode of 147
479 Ma, subordinate age modes of 331 Ma and 428 Ma, and four Precambrian grains (Yokelson
480 et al., 2015). In the middle strata of the Gravina belt (specifically the top of the Seymour
481 Canal Formation), 'Fort Point' samples reveal dominant age modes of 116 and 432 Ma, a
482 subordinate age mode of 360 Ma, and five Precambrian grains (Yokelson et al., 2015). And
483 in the uppermost strata of the Gravina belt (specifically the Treadwell Formation), 'Berners
484 Bay' samples contain a dominant age mode of 154 Ma, subordinate age modes of 119, 426,
485 and 445 Ma, and ten Precambrian grains (Yokelson et al., 2015). In addition, 'Pybus Bay'
486 samples from either the middle of the Gravina belt strata (specifically the top of the
487 Seymour Canal Formation according to Kapp and Gehrels, 1998), or from the from the base
488 of the Gravina belt strata (specifically the base of the Seymour Canal Formation according
489 to Yokelson et al., 2015), reveal a single dominant age mode of 147 Ma, a couple of
490 Paleozoic grains, and no Precambrian grains, with an average distribution of detrital zircon
491 ages of ~M100 P<1Pc0 (Yokelson et al., 2015).
492
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493 The detrital zircon age spectra of the Dezadeash Formation, Nutzotin Mountains
494 sequence and Gravina belt are all characterized by a dominant Late Jurassic to Early
495 Cretaceous age mode, variable amounts of Paleozoic grains or no Paleozoic grains, and
496 several Precambrian grains or no Precambrian grains. Hults et al. (2013) proposed that this
497 'southern flysch belt' (in addition to several unnamed units in Alaska), with an overall
498 average distribution of detrital zircon ages of ~M94 P1 Pc5, reflects derivation from the
499 Chitina arc and the WCT, and is distinctly different from their 'northern flysch belt', which
500 includes the Cretaceous Kahiltna and Kuskokwim units, with an overall average
501 distribution of detrital zircon ages of ~M54 P14 Pc32, that reflects derivation from the YCT.
502
503 Major Elements
504 Results
505 Results of the whole rock geochemical analyses are provided in Supplementary
506 Table S6 and re-calculated geochemical data is shown in Table 6. The major elements
507 Al2O3 and Na2O of sandstone show an increase in abundance with increasing SiO2 content
508 (Fig. 12), while MgO, CaO, and P2O5 show a decrease in abundance. Major elements
509 Fe2O3, TiO2, and K2O show no trend. The major elements of mudstone show no strong
510 trend with increasing SiO2 concentration (Fig. 12), and tend to plot as a group at the higher
511 SiO2 end of the sandstone trends. The SiO2 and Al2O3 concentration of sandstones and
512 mudstones are similar, ranging from ~40-60 % and ~12-17 %, respectively. Hemipelagites
513 have considerably less SiO2 (~13-28 %) and Al2O3 (~4-9 %), but higher CaO
514 concentrations (>30%) relative to either sandstones or mudstones. The hemipelagites also
515 have higher MnO values (averaging ~0.3 %) and P2O5 values (several >1%) compared to
516 sandstones and mudstones.
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517 The SiO2/Al2O3 ratio (Table 6) is the same for both sandstones and mudstones
518 (~3.6), whereas hemipelagites have a slightly lower ratio (~3.3). The Fe2O3/K2O ratio
519 increases from sandstones (~4.9) to mudstones (~5.2), and decreases for hemipelagites
520 (~3.0). The A-CN-K or feldspar ternary diagram (Fig. 13), with apexes corresponding to
521 Al2O3-(CaO*+Na2O)-K2O (Fedo et al., 1995; Nesbitt, 2003), shows that the majority of the
522 sandstones plot close to, or below, the composition of unweathered igneous rocks and
523 plagioclase. They also have a Chemical Index of Alteration (CIA) ranging from ~20-50
524 (Table 6), indicating they are unweathered or have undergone only incipient weathering.
525 Furthermore, their average Index of Compositional Variability (ICV, Table 6), calculated as
526 [Fe2O3+CaO+Na2O+K2O+MgO+MnO+TiO2)/Al2O3] (Cox et al., 1995), is >1,
527 corresponding to first-cycle input or compositional immaturity (Cox et al., 1995).
528 Mudstones generally plot between the composition of unweathered igneous rocks and
529 plagioclase, and the average shale composition (Fig. 13). Their CIA ranges from ~50-70,
530 indicating they are moderately weathered (Fedo et al., 1995; Nesbitt, 2003), and their
531 average ICV is also >1, corresponding to first-cycle input or compositional immaturity
532 (Cox et al., 1995). Both sandstone and mudstone compositions deviate slightly from the A-
533 CN join towards the K-apex. Hemipelagite compositions cluster near the CN-apex on the
534 ternary diagram (Fig. 13), with CIA ranging from ~5-15, and their average ICV is > 1.
535
536 Interpretations
537 The SiO2/Al2O3 ratio is an index of mineralogical maturity (Taylor and McLennan,
538 1985), and both sandstones and mudstones have similar values (~3.6). The Fe2O3/K2O ratio
539 is an index of mineralogical stability (Taylor and McLennan, 1985), and values increase
540 from sandstones (~4.9) to mudstones (~5.2). The major element A-CN-K ternary diagram
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541 (Fig. 13) and CIA of Fedo et al. (1995) monitors only feldspar weathering, but these two
542 parameters, together with the index of mineralogical maturity and the index of
543 mineralogical stability, show that mudstones are slightly more weathered than sandstones,
544 as might be expected. In addition, the siliciclastic compositions deviate slightly from the A-
545 CN join towards the K-apex, suggesting minor post-depositional K metasomatism.
546 Hemipelagites were initially classified as biogenic oozes (> 75 % biogenics) based
547 on their vigorous reaction to HCl acid in the field (Lowey, 2007), but according to their
548 CaO content (29-43%, and assuming all of it was biogenic in origin) they are more properly
549 classified as biogenic mud (25-50% biogenics; Pickering et al., 1989). The hemipelagites
550 are geochemically distinct from the sandstones and mudstones on the basis of their higher
551 CaO, MnO (0.3 %), and P2O5 (~ >1%) contents. The anonymously low CIA values for the
552 hemipelagites is attributed to their high CaO content, because in calculating the CIA value
553 CaO is assumed to be associated only with silicate minerals.
554
555 Trace Elements, Rare Earth Elements, and Isotopes
556 Results
557 Sandstones have an average total rare earth element (∑REE) concentration of ~88
558 ppm (Table 6), comprising an average light rare earth element (∑LREE) concentration of
559 ~76 ppm and an average heavy rare earth element (∑HREE) concentration of ~12 ppm,
560 with an average ∑LREE/∑HREE ratio of ~6. Mudstones have a slightly lower average
561 ∑REE concentration of ~83 ppm, consisting of an average ∑LREE concentration of ~70
562 ppm and an average ∑HREE concentration of ~12 ppm, with an average ∑LREE/∑HREE
563 ratio of ~5. Hemipelagites have a significantly higher average ∑REE concentration of ~141
564 ppm, comprising an average ∑LREE concentration of ~127 ppm, but an average ∑HREE
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565 concentration of only ~13 ppm, corresponding to an average ∑LREE/∑HREE ratio of ~9.
566 Chondrite-normalized rare earth element plots (Fig. 14A, B, C) of sandstone, mudstone,
567 and hemipelagite samples display similar, parallel, listric-shaped profiles with significant
568 LREE enrichment (x40-100) that is broadly decreasing, moderate middle rare earth-element
569 (MREE) enrichment (x10-20), and minor HREE enrichment (x10). The lack of significant
570 Ce and Eu anomalies relative to chondrite appears to be present in all profiles, with the
571 exception of hemipelagites, for which one sample displays a positive Eu anomaly. The
572 chontrite-normalized ratio of La/YbN indicates moderate fractionation of LREE in
573 sandstones (~5.81) and mudstones (~4.29), compared to greater fractionation of LREE in
574 hemipelagites (~14.34), whereas the chontrite-normalized ratio of Gd/YbN indicates minor
575 fractionation of HREE in sandstones (~1.46) and mudstones (~1.39), compared to slightly
576 greater fractionation of HREE in hemipelagites (~1.56).
577 On the Lu/Hf versus Sm/Nd diagram (Fig. 15), sandstones plot in the field for
578 turbidites and along the trend for magmatic differentiation (close to the composition of
579 granitoids, or GTS, with SiO2 >55%; Hawkesworth et al., 2010), whereas mudstones are
580 concentrated in the field for cratonic shales. Hemipelagites have considerable scatter: one
581 sample plots in the field for normal clays, but most of the samples have compositions
582 between the field for normal clays and the field for red clays (not shown in Figure 15, but
583 directly above the field for normal clay and above the Lu/Hf value of 0.25).
584 On the Th/Sc versus Zr/Sc diagram (Fig. 16), sandstones and mudstones plot within
585 the field for active margin turbidites and along the trend for compositional variations. This
586 diagram also indicates that element abundances in sandstones and mudstones are due to the
587 composition of the source area (which was andesitic in composition), rather than sediment
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588 recycling or sorting. Element abundances in hemipelagites also appear to be due to
589 compositional variations in the source area.
590 Tectonic discrimination diagrams of La versus Th (Fig. 17A) and Sc-Th-Zr/10 (Fig.
591 17B) reveal that sandstone and mudstone samples plot mainly in the ocean island arc field,
592 with some overlap in the continental arc field. Hemipelagites also plot in or near the ocean
593 island arc field (Fig. 17A).
594 The initial εNd (149) values for the time corresponding to deposition (~149 Ma) range
595 from +1.6 to +4.6 for sandstones, +0.1 to +3.3 for mudstones, and -2.0 to +2.5 for
596 hemipelagites (Table 7). Figure 18 shows histograms of sandstone, mudstone, and
597 hemipelagite samples for εNd (149) (Fig. 18A), Eu/Eu* (the Eu value expected for a smooth
598 chondrite-normalized REE profile) (Fig. 18B), Th/Sc (Fig. 18C), and Th/U (Fig. 18D),
599 based on values defined by McLennan at al. (1993). The εNd (149) values are inconclusive
600 with respect to the fields defied by McLennan et al. (1993), although these fields were
601 defined for modern sediments only. The Eu/Eu*, Th/Sc, and Th/U values all fall within the
602 fields for sediments derived from a young (i.e., juvenile or depleted mantle source),
603 undifferentiated arc.
604 The present day εNd (0) values for sandstones range from +0.4 to +3.4; mudstones
605 range from 0 to +4.2; and hemipelagites range from -3.2 to +1.4 (Table 7). A plot of εNd(0)
606 versus 147Sm/144Nd (Fig. 19) reveals that the sandstone, mudstone, and hemipelagite
607 samples have similar Sm-Nd characteristics as the Gravina belt and are within the Sm-Nd
608 isotopic field of the Alexander and Wrangellia terranes that form part of the WCT. The
609 depleted mantle model age for sandstones range from 0.69-0.94 Ga; mudstones range from
610 0.9 -1.0 Ga; and hemipelagites range from 0.75-1.27 Ga.
611
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612 Interpretations
613 The ∑REE for sandstones (~88 ppm) is within the range of Phanerozoic greywackes
614 (~45-207 ppm) and modern turbidite sands (~50-195 ppm) (Taylor and McLennan, 1985).
615 The ∑REE for mudstones (~84 ppm) is lower than North American Shale Composite
616 (NASC) (~173) and Post Archean Australian Shale (PAAS) (~187) (Taylor and McLennan,
617 1985). The relatively low ∑REE displayed by both sandstones and mudstones is
618 characteristic of sediments derived from young, undifferentiated arcs (McLennan et al.,
619 1993). The ∑LREE/∑HREE ratio for sandstones (~6) and mudstones (~5), is slightly less
620 than NASC (~7.1) and total crust (~7.2), but less than Global Subducting Sediment
621 (GLOSS) (~8.8), PAAS (~9.45), and upper crust (~9.47) (Taylor and McLennan, 1985).
622 However, the SiO2/Al2O3 ratio for sandstones (~3.55-3.68) and mudstones (~3.63) is
623 similar to andesite (~3.39), NASC (~3.8) and total crust (~3.8), but lower than GLOSS
624 ~4.9, or upper crust ~4.3 (Taylor and McLennan, 1985). Therefore, the lower observed
625 ∑LREE/∑HREE ratio for the sandstones and mudstones is probably not due to quartz
626 dilution, but rather mixing of a juvenile and more evolved source. Furthermore, the
627 siliciclastics lack significant Eu anomalies on chondrite normalized REE diagrams (Fig.
628 14A, B, C), making these profiles dissimilar to the profiles for GLOSS, NASC, PAAS,
629 upper crust, and middle crust (Fig. 14D), but they closely match the profile for total crust.
630 The lack of significant Eu anomalies (Eu/Eu*) in sandstones (~0.97-1.04) and mudstones
631 (~1.01), both of which are close to Eu anomalies for andesites (~0.95-1.07; Taylor and
632 McLennan, 1985), further substantiates a young, undifferentiated arc provenance and are
633 characteristic of first-cycle volcanogenic material derived from an adjacent magmatic arc
634 (Taylor and McLennan, 1985).
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635 The moderate (La/Yb)N values for the sandstones (~5.81) and mudstones (~4.29),
636 together with the low (Gd/Yb)N values for these rocks (~1.46 and ~1.39, respectively), also
637 indicates only moderate igneous differentiation of the source rocks, corroborating the Lu/Hf
638 and Sm/Nd results (Fig. 15) and the Th/Sc vs Zr/Sc results (Fig. 16).
639 The Lu/Hf ratio is an index of igneous differentiation comparing compatible HREE
640 Lu and incompatible high field strength element Hf, whereas the Sm/Nd ratio is also an
641 index of igneous differentiation comparing incompatible LREE Sm (which tends to
642 concentrate in the mantle) and moderately compatible LREE Nd (which tends to
643 concentrate in continental crust); both ratios decrease with increasing differentiation
644 (Taylor and McLennan, 1985; McLennan et al., 1993). The Lu/Hf vs Sm/Nd plot (Fig. 15)
645 for the siliciclastics suggests that source rocks were granitoid in composition (i.e., SiO2
646 >55%; Hawkesworth et al., 2010), compatible with an andesitic composition determined
647 from the Th/Sc vs Zr/Sc diagram (Fig. 16). Furthermore, the siliciclastics display lower
648 Lu/Hf and Sm/Nd ratios than island arcs, indicating the sediments appear to be more
649 chemically evolved than volcanic arc rocks, but higher Lu/Hf and Sm/Nd ratios than Upper
650 Continental Crust (UCC), suggesting the sediments appear to be less chemically evolved
651 than continental crust rocks
652 The Th/Sc ratio is an index of igneous differentiation that compares incompatible
653 Th to moderately compatible Sc, whereas the Zr/Sc ratio is an index of zircon enrichment
654 that compares moderately incompatible Zr to moderately compatible Sc (Taylor and
655 McLennan, 1985; McLennan et al., 1993). The Th/Sc vs Zr/Sc plot (Fig. 16) documents
656 moderate igneous differentiation corresponding to a source area that was andesitic in
657 composition, and the low zircon enrichment (low sediment recycling) is compatible with
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658 the CIA results. Low Th/Sc ratios also suggest that the source was a young (juvenile or
659 mantle derived), undifferentiated arc (McLennan, 1989; McLennan et al., 1993).
660 Sandstone and mudstone compositions plotted on the La vs Th and La-Sc-Th
661 tectonic discriminant diagrams of Bhatia and Crook (1986) suggest an ocean island arc
662 provenance with some input from a continental arc (Fig. 17). Bhatia and Crook (1986)
663 define a continental arc as an island arc formed on well developed continental crust or a
664 thin continental margin.
665 The Sm-Nd isotopic systematics for sandstones (εNd(149 Ma)=+1.6 to +4.6) and
666 mudstones (εNd(149 Ma) =+0.1 to +3.3) indicate primarily a depleted mantle source with
667 some mixing of an older crustal source (Fig.18). Mixing of an older crustal source is
668 supported by the TDM age for sandstones (0.7-0.9 Ga) and mudstones (0.9-1.0), which
669 depart significantly from their stratigraphic age (~149 Ma), implying magmatic or
670 sedimentary re-cycling of older material. The εNd vs Age plot (Fig. 19) shows that
671 siliciclastics plot within the fields for the Alexander, Wrangellia, and Stikine terranes, and
672 the Gravina belt.
673 The hemipelagites not only have higher CaO, MnO, and P2O5 contents compared to
674 that of sandstones and mudstones, but they also have higher ∑REE (~141 ppm)
675 concentrations and ∑LREE/∑HREE ratios (~9, which is similar to values for GLOSS,
676 PAAS, and UCC). The hemipelagites also display significant negative Ce anomalies
677 (~0.83) and positive Eu anomalies (~1.33), and somewhat more evolved initial εNd values (-
678 2.0 to +2.5) and older depleted mantle model ages (0.75-1.27 Ga) than the sandstones and
679 mudstones.
680 Generally, hemipelagites are thought to have a mixed origin (components of
681 lithogenous, biogenous, hydrogenous, and cosmogenous origin; Seibold and Berger, 1982),
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682 which could result in a complicated geochemical fingerprint of their provenance. The
683 ∑LREE enrichment, evolved initial εNd values, and older TDM ages of the hemipelagites
684 suggest mixing with continental derived material, possibly via eolian dust (e.g., Rea, 1994).
685 Alternatively, the greater MnO and P2O5 compositions, together with the negative Ce and
686 positive Eu anomalies displayed by the hemipelagites, may indicate preferential
687 concentration of LREE in post-depositional authigenic apatite or monazite (cf., Milodowski
688 and Zalasiewicz, 1991; Ball et al., 1992; Ehrenberg and Nadeau, 2002; Evans et al., 2009;
689 Guo, 2010). Deciphering the complex geochemical signal in the hemipelagites is the focus
690 of ongoing research.
691
692 Discussion
693 Directional Provenance Indicators
694 Previous researchers (e.g., Nokleberg et al., 1985; McClelland et al., 1992; Kapp
695 and Gehrels, 1998; Nokleberg and Richter, 2007; Yokelson et al., 2015) appear to have
696 overlooked the utility of existing paleocurrent data for the Gravina-Nutzotin belt, thereby
697 obfuscating the provenance record. However, paleocurrent data for the Dezadeash
698 Formation are robust (i.e., ~600 measurements of sole marks, cross laminations, slump
699 folds, and a debris flow channel distributed vertically and laterally throughout the strata)
700 and documents a sediment source from the west (i.e., the WCT) with a paleoslope dipping
701 eastward in the direction of Laurasia. Paleocurrent data from the Nutzotin Mountains
702 sequence are less robust (i.e., ~400 measurements of mainly cross laminations and clast
703 imbrications), but also suggests a sediment source to the west. There are no directional
704 provenance indicators linking the Dezadeash Formation and Nutzotin Mountains sequence
705 with inboard terranes (i.e., Yukon-Tanana, Slide Mountain, Cache Creek, Quesnel, and
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706 Stikine). Therefore, the paleocurrent data for the Dezadeash Formation and Nutzotin
707 Mountains sequence constrain the provenance to the west. Paleocurrent data for the
708 Gravina belt are not robust (i.e., ~30 measurements of mainly cross laminations), but
709 Cohen et al. (1985) inferred a sediment source to the west based on a dominance of 160-90
710 Ma 40Ar /39Ar ages from biotite and amphibole grains in Gravina belt strata that were
711 interpreted to have been derived from the Chitina arc. If the Gravina belt formed in the
712 same overall tectonic setting as the Dezadeash Formation and Nutzotin Mountains
713 sequence, then an overall sediment source to the west for the Gravina-Nutzotin belt is
714 likely, as originally proposed by Monger et al. (1983).
715 Although the eastern margin of the Dezadeash Formation is not preserved or has not
716 been recognized, it is conceivable that sediment could have been shed from the east (i.e.,
717 YCT). However, any potentially east-derived sediment would represent an entirely
718 different sediment dispersal system than the Dezadeash Formation, interpreted as an
719 eastward prograding point-source submarine fan (Eisbacher, 1976; Lowey, 2007). That is,
720 separate 'western facies' (Dezadeash Formation) and 'eastern facies' (not preserved or not
721 recognized yet) are possible, similar to that proposed for the Gravina belt (Yokelson et al.,
722 2015).
723
724 Compositional Provenance Indicators
725 Consideration of the directional provenance indicators is a requisite for the
726 interpretation of the compositional provenance indicators. Namely, paleocurrent data for
727 the Dezadeash Formation suggests that sediment was derived exclusively from the west
728 (i.e., the WCT and Chitina arc). Inboard terranes (e.g., Yukon-Tanana, Slide Mountain,
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729 Cache Creek, Quesnel, and Stikine) did not contribute sediment, with the exception of
730 perhaps minor additions to hemipelagite beds.
731 Conglomerate clasts in the Dezadeash Formation were likely derived locally from
732 the WCT and Chitina arc: volcanic and igneous mafic clasts match the composition of the
733 Permian Skolai Group and Triassic Nikolai Formation; sedimentary clasts resemble the
734 compositions of an unnamed upper Paleozoic-upper Triassic map unit (uPpc), the Permian
735 Skolai Group, Triassic McCarthy Formation, and the Chitistone and Nizina Limestone
736 units; and plutonic clasts match the composition of the Jura-Cretaceous Saint Elias Plutonic
737 Suite (Dodds and Campbell, 1992). Even though Berg et al. (1972) suggested that clasts of
738 white quartz and metamorphic rocks were derived from the Yukon-Tanana terrane, these
739 lithologies are also present in the WCT. Detritus sourced from the WCT is supported by the
740 Triassic (Late Norian) conodont age obtained from the limestone clast in the Dezadeash
741 Formation. This age is identical to that of an unnamed upper Paleozoic-upper Triassic map
742 unit (uPpc) and the Triassic McCarthy Formation, both of which contain similar conodont
743 species (Dodds et al, 1993). The K-Ar age (~144 Ma) from the diorite pebble in the
744 Dezadeash Formation is compatible with K-Ar ages for the Saint Elias Plutonic Suite
745 (Dodds and Campbell, 1992), interpreted as the roots of the Chitina arc (Lowey, 2011).
746 Conglomerate clast and sandstone frameworks modes from the Dezadeash
747 Formation are compatible with derivation from the Chitina arc according to various tectonic
748 discrimination diagrams (Figs. 7, 8). As discussed by Boggs (2009), the larger particle size
749 of conglomerate may make them more reliable provenance indicators than sandstone, with
750 the caveat that conglomerate clasts have not been removed during weathering or
751 transportation. The preservation of carbonate clasts in conglomerate and carbonate grains in
752 sandstone from the Dezadeash Formation, together with the results of the A-CN-K feldspar
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753 weathering diagram (Fig. 13) for sandstone from the Dezadeash Formation, suggests that
754 the conglomerate, like the sandstone, is only moderately weathered.
755 Detritus sourced from the Chitina arc is supported by the detrital zircon age mode
756 between ~165-150 Ma from the Dezadeash Formation (Fig. 10), which matches the 160-
757 140 Ma age of the Chitina arc (Plafker et al., 1989; Nokleberg et al., 1994; Roeske et al.,
758 2003), and is close to the age of the Chitina arc as determined from the age of magmatic
759 zircons recovered from a tuff bed in the Dezadeash Formation (~149 Ma; Lowey, 2011).
760 The somewhat older detrital zircon ages (207-164 Ma) obtained from the sandstones in the
761 Dezadeash Formation may indicate proximity to the Talkeetna arc, which was apparently
762 active ~205-155 Ma (Amato et al., 2007; and zircon data compiled by Hampton et al.,
763 2010). The Dezadeash Formation contains only several Paleozoic grains and several
764 Precambrian grains, although zircons of these ages are present in greater abundance in the
765 WCT ( Gehrels et al., 1996; Grove et al., 2008; Beranek et al., 2012; Beranek et al., 2013).
766 The lack of abundant detrital zircons of Paleozoic age is not uncommon in samples from
767 the Gravina-Nutzotin belt: samples from the Nutzotin Mountains sequence contain no
768 Paleozoic zircons (Manuszak et al., 2007), or only a few grains (Hults et al., 2013), and
769 'Pybus Bay' samples from the Gravina belt contain no Paleozoic zircons (Kapp and Gehrels,
770 1998; Yokelson et al., 2015). Generally, samples from the Gravina belt contain a significant
771 population of Paleozoic zircons (Kapp and Gehrels, 1998; Yokelson et al., 2015). The
772 difference in the population of Paleozoic zircons in the Gravina belt compared to the
773 Dezadeash Formation and Nutzotin Mountains sequence may simply reflect differences in
774 the number of samples (twelve from the Gravina belt versus two from the Dezadeash
775 Formation and two from the Nutzotin Mountains sequence). Another explanation is that
776 Paleozoic zircons are more readily available from the Alexander terrane, which underlies
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777 the Gravina belt, compared to the Wrangellia terrane, which underlies the Dezadeash
778 Formation and Nutzotin Mountains sequence (Hults et al., 2013).
779 The geochemistry of sandstone and mudstone beds from the Dezadeash
780 Formation is characteristic of sediments sourced from young, undifferentiated arcs,
781 compatible with derivation from the Chitina arc, as revealed by various tectonic
782 discrimination diagrams (Figs. 15, 16, 17, 18). Sm-Nd systematics of sandstone and
783 mudstone beds from the Dezadeash Formation are compatible with the strata being sourced
784 from the WCT and the Chitina arc (Fig. 19).
785
786 Tectonic Setting
787 Due to uncertainties regarding the timing and location of collision of the WCT with
788 Laurasia, and the number and polarity of Mesozoic magmatic arcs, the tectonic setting of
789 the WCT with respect to Laurasia remains unresolved. As a result, various tectonic settings
790 have been proposed and these are summarized by and Kapp and Gehrels (1997) and
791 Sigloch and Mihalynuk (2017). Tectonic settings relevant to the origin of the Gravina-
792 Nutzotin belt can be subdivided into east-dipping subduction and west-dipping subduction
793 models (Fig. 20). East-dipping subduction models include: 1) a precollisional, ocean basin
794 scenario (Fig. 20A) with east-dipping subduction beneath the WCT, east-dipping
795 subduction beneath the accreted YCT margin, and an ocean of indeterminant width
796 separating the WCT from the YCT (Monger et al., 1982); 2) a syncollisional, retroarc
797 foreland basin scenario (Fig. 20B) with east-dipping subduction beneath the WCT and east-
798 dipping subduction beneath the YCT, in which the WCT is colliding progressively from
799 the south to the north with the accreted YCT (Trop et al., 2002); and 3) a rift or
800 transtensional basin scenario (Fig. 20C) with east-dipping subduction beneath the WCT and
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801 a narrow ocean separating the WCT from the accreted YCT (Yokelson et al., 2015). The
802 only west-dipping subduction model is a precollisional, forearc basin scenario (Fig. 20D),
803 with west-dipping subduction beneath the WCT and a wide ocean separating the WCT
804 from the accreted YCT (Sigloch and Mihalynuk, 2017).
805 The backarc, rift/transtensional, and retroarc foreland basin scenarios are based on
806 the premise that a provenance link exists between the Gravina-Nutzotin belt and the
807 western margin of Laurasia: namely, that clasts of white vein quartz and metamorphic rocks
808 in the Nutzotin Mountains sequence (Berg et al. 1972; Richter, 1976; Nokleberg et al.,
809 1985; Manuzsak et al., 2007), and 380-330 and >900 Ma detrital zircons in the Gravina belt
810 (Kapp and Gehrels, 1998) were derived from the YCT. However, clasts representing these
811 compositions and zircons representing these ages can be accounted for in the WCT.
812 Support for the rift/transtensional and retroarc foreland basin models is further weakened
813 by the detrital zircon signature of the Gravina-Nutzotin belt. According to Cawood et al.
814 (2012), the tectonic setting of a basin can be inferred from the detrital zircon age spectra
815 deposited in the strata. The Dezadeash Formation, Nutzotin Mountains sequence, and
816 Gravina belt display detrital zircon age spectra that are unlike those for collisional settings
817 (foreland basins) and extensional settings (rift/transtensional basins), characterized by a
818 greater proportion of older zircon ages compared to the depositional age of the strata), but
819 match those for convergent settings (including trench, forearc and backarc basins), which
820 are dominated by zircon ages close to the depositional age of the sediment (Cawood et al.,
821 2012).
822 The preferred tectonic setting, based in part on the reinterpretation by Sigloch and
823 Mihalynuk (2013, 2017) of the tectonic setting of the western margin of Laurasia (i.e., the
824 North American Cordillera), is the forearc basin scenario (Fig. 20D). Using tomographic
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825 images of lower-mantle slabs, Sigloch and Mihalynuk (2013, 2017) suggested that
826 westward subduction of the Mezcalera slab beneath the WCT consumed the large
827 intervening 'Mezcalera ocean basin' separating the WCT from Laurasia. The basin fill
828 (mainly deep marine turbidites), preserved basin dimensions (tens of kilometres wide and
829 hundreds of kilometres long, with sediment thickness of ~3,000 m), and basin architecture
830 (flanked by a volocanoplutonic arc) of Dezadeash Formation is consistent with modern and
831 ancient forearc basins documented by Dickinson (1995). In addition, the depositional
832 architecture of the Dezadeash Formation and Nutzotin Mountains sequence supports a
833 forearc basin scenario: the Dezadeash Formation, interpreted as the distal facies of the
834 basin, comprises lower to middle submarine fan deposits that display no apparent, overall
835 vertical trend (Lowey, 2007), whereas the Nutzotin Mountains sequence, interpreted as the
836 proximal facies of the basin, comprises upper submarine fan to shelf deposits that display a
837 general upward-shallowing and upward-coarsening sequence (Manuzsak et al., 2007).
838 According to Dickinson (1995), one of the characteristics of a forearc basin is a
839 depositional architecture that shoals upward from turbidite facies to shelf facies.
840 The directional and compositional provenance indicators for the Dezadeash
841 Formation cannot indicate with certainty the tectonic setting of the Gravina-Nutzotin belt
842 because the eastern margin of the Dezadeash Formation is no longer preserved (or has not
843 been recognized). Reconciling which scenario is correct may be difficult, or impossible,
844 given the variable preservation potential of different tectonic segments along a converging
845 and colliding arc (Draut and Clift, 2013).
846
847 Conclusions
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848 Compositional provenance data from submarine fan deposits of the Dezadeash
849 Formation, including conglomerate pebble-counts, a hornblend K-Ar age from a diorite
850 pebble, a conodont age from a limestone cobble, sandstone point-counts, U-Pb age of
851 detrital zircons from sandstones, and the lithogeochemistry of sandstones, mudstones and
852 hemipelagites, including major elements, trace elements, rare earth elements, and Sm-Nd
853 isotopes, interpreted in the context of directional provenance indicators that document
854 sediment was derived from the west, lead to the following conclusions:
855
856 1 The framework composition of conglomerates is dominated by andesite clasts,
857 with lesser amounts of sedimentary, plutonic, and quartz clasts. A hornblende K-Ar age
858 from a diorite clast and a conodont age from a limestone clast is compatible with the WCT
859 as the sediment source. The P-S-V ternary diagram suggests that conglomerates were
860 derived mainly from an undissected arc compatible with the Chitina arc built on the WCT.
861
862 2 The framework composition of sandstones is dominated by lithic grains (mainly
863 volcanic grains exhibiting felsitic and lathwork textures). Sandstone ternary diagrams of
864 Qt-F-L and Qm-Fl-T suggest derivation from a transitional to undissected arc; high P/F
865 ratios (~>0.8) and Lv/L ratios (~>0.9) also suggest an undissected arc provenance.
866
867 3 The U-Pb age range of 165-155 Ma from detrital zircons in the sandstones is
868 compatible with their derivation from the contemporaneous Chitina volcanic arc.
869
870 4 The lithogeochemistry of sandstones and mudstones is similar with regards to
871 major elements (e.g., SiO2/Al2O3 ~3.6), rare earth elements (e.g., ∑REE ~83-88 ppm,
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872 ∑LREE/∑HREE ~5-6, and lack of Ce and Eu anomalies), various plots of Lu/Hf vs Sm/Nd,
873 Th/Sc vs Zr/Sc, La vs Th, La-Sc-Th, and Sc-Th-Zr plots, and Sm-Nd isotopic systematics
874 (e.g., overrlapping initial εNd values, with sandstones ranging from +1.6 to +4.6, and
875 mudstones from +0.1 to +3.3). The similarities in their geochemistry implies they were
876 derived from the same young (dominantly mantle derived), undifferentiated volcanic arc,
877 with mudstones being more weathered than sandstones (e.g., CIA values range from ~50-
878 70, compared to ~20-50 for sandstones).
879
880 5 The lithogeochemistry of the hemipelagites is distinct from the sandstones and
881 mudstones, particularly with regards to several major elements (e.g., higher CaO, MnO, and
882 P2O5 contents), rare earth elements (e.g., ∑REE ~141 ppm, ∑LREE/∑HREE ~9, and
883 negative Ce anomalies and positive Eu anomalies), and Sm-Nd isotopic systematics (e.g.,
884 initial εNd values range from -2.0 to +2.5). Their geochemistry implies a mixed (i.e., more
885 evolved) provenance and/or diagenetic alteration.
886
887 Integrated provenance analysis of the Dezadeash Formation suggests that
888 conglomerate, sandstone, and mudstone were shed eastward from the undissected Chitina
889 magmatic arc and the WCT into an adjacent flysch basin. The Chitina arc consisted mainly
890 of undifferentiated andesitic volcanic rocks built on the WCT. The andesitic rocks were
891 sourced from the depleted mantle with some mixing of crustal contaminant (i.e., the WCT
892 terrane proxing for continental crust). Hemipelagites may have a mixed (partly continental-
893 derived) provenance and/or have undergone diagenetic modification of their
894 lithogeochemistry. Given that the eastern margin of the Dezadeash Formation is not
895 preserved, the provenance dataset presented herein does not unequivocally constrain the
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896 tectonic setting of the Gravina-Nutzotin belt, but strongly suggests a convergent plate
897 margin setting.
898
899 Acknowledgements
900 Thanks to Werner Liebau for his outstanding assistance in the field, pilot Doug Makkonen
901 for his expert helicopter flying, and Jochen Mezger for his thoughtful discussions. George
902 Gehrels graciously analyzed the zircons. I am grateful to CJES Editor Ali Polat and an
903 anonymous reviewer for making a thorough examination of this manuscript and particularly
904 Todd Lamaskin for providing thoughtful, constructive comments.
905
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1328
1329 Figure Captions
1330
1331 Figure. 1. Location map and geologic setting of the Dezadeash Formation, Yukon
1332 (compiled from Makevet, 1978; Wheeler and McFeely, 1991; and Monger, 2014).
1333 AT=Alexander terrane, CC=Cache Creek terrane, PT=Peninsular terrane, ST=Stikine
1334 terrane, YTT=Yukon-Tanana terrane, WT=Wrangellia terrane. Kootenay , Cassiar, and
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1335 Quesnel terranes not shown. Other Jura-Cretaceous basins not part of the Gravina-Nutzotin
1336 belt: KBa=Kahiltna basin-Alaska Range, KBt=Kahiltna basin-Talkeetna Mountains,
1337 MB=Matanuska Valley basin, WB=Wrangell Mountains basin. T=Talkeetna arc,
1338 C=Chitina arc, A=Chisana arc.
1339
1340 Figure. 2. Generalized stratigraphic sections showing lithologic comparison of strata from
1341 different parts of the Gravina-Nutzotin belt (after Berg et al., 1972; McClelland et al., 1992;
1342 Cohen and Lundberg, 1993; Plafker and Berg, 1994; and Trop et al., 2002).
1343
1344 Figure. 3. Location of measured sections (numbers) in the Dezadeash Formation, Yukon,
1345 from which samples were collected (modified from Lowey, 2007).
1346
1347 Figure. 4. Photographs of representative lithofacies that were sampled from the Dezadeash
1348 Formation, Yukon. A) Disorganized gravelly mudstone, long white interval on Jacob's Staff
1349 is 0.5 m long. B) Thick-bedded sandstone, 1.5 m long Jacob's Staff for scale. C) Medium-
1350 to thin-bedded sandstone, 1.5 m long Jacob's Staff for scale. D) Mudstone, green squares at
1351 top of scale card are 1 cm long. E) Hemipelagite bed (brown bed). Brown interval on
1352 Jacob's Staff is 0.1 m long.
1353
1354 Figure. 5. Directional provenance indicators from the Gravina-Nutzotin belt: the Nutzotin
1355 Mountains sequence compiled from Kozinski (1985) and Manuzsak et al. (2007); the
1356 Dezadeash Formation compiled after Eisbacher (1976) and Lowey (1980, 1998); and the
1357 Gravina Belt compiled after Cohen (1992).
1358
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1359 Figure. 6. Pebble-count compositions of conglomerates from the Dezadeash Formation,
1360 Yukon. A) P+M-S-V ternary diagram. Classification after Cox and Low (1995). B) P-S-V
1361 ternary diagram. Classification after Dickie and Hein (1995). Data sources as follows:
1362 Gravina belt, Cohen (1992); Nutzotin Mountains sequence, Manuszak et al. (2007).
1363 P=plutonic clasts; M=metamorphic clasts; S=sedimentary clasts; and V=volcanic clasts.
1364
1365 Figure. 7. Point-count compositions of sandstones from the Dezadeash Formation, Yukon.
1366 A) Qt-F-L ternary diagram. Classification after Dickinson et al. (1983). B) Qm-P-K ternary
1367 diagram. Classification after Dickinson and Suczek (1979). Data sources as follows:
1368 Gravina belt, Cohen and Lundberg (1993); Nutzotin Mountains sequence, Kozinski (1985)
1369 and Manuszak et al. (2007). Qt=total quartz grains, including monocrystalline and
1370 polycrystalline grains, and chert; F=total feldspar grains; L=total lithic grains; Qm-
1371 monocrystalline quartz grains; P=plagioclase grains; and K=potassium feldspar grains.
1372
1373 Figure. 8. Point-count compositions of sandstones from the Dezadeash Formation, Yukon.
1374 A) Qp-Ls-Lv ternary diagram. Classification after Dickinson and Suczek (1979). B) Lm-
1375 Ls-Lv ternary diagram. Classification after Marsaglia and Ingersoll (1992). Data sources as
1376 follows: Gravina belt, Cohen and Lundberg (1993); Nutzotin Mountains sequence,
1377 Kozinski (1985) and Manuszak et al. (2007). Qp=polycrystalline quartz grains;
1378 Ls=sedimentary lithic grains; Lv=volcanic lithic grains; Lm=metamorphic lithic grains.
1379
1380 Figure. 9. Pb/U concordia diagrams of analyses of single detrital zircon grains from the
1381 Dezadeash Formation, Yukon. A) Sample GL-74A. B) Sample GL-74B. Error ellipses are
1382 shown at 1σ (plotted with the programs of Ludwig, 2008).
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1383
1384 Figure. 10. Pb/U histograms and age spectra of single detrital zircon grains from the
1385 Dezadeash Formation, Yukon. A) Sample GL-74A. B) Sample GL-74B. Error ellipses are
1386 shown at 1σ (plotted with the programs of Ludwig, 2008).
1387
1388 Figure. 11. Comparison of Pb/U age spectra detrital zircon grains for Yukon-Tanana
1389 terrane (YTT), Wrangellia composite terrane (WCT), and Gravina-Nutzotin belt. Data
1390 source as follows: Kapp and Gehrels (1998), and Nelson and Gehrels (2007).
1391
1392 Figure. 12. Harker diagrams of sandstone (yellow squares), mudstone (green circles) and
1393 hemipelagite (blue triangles) samples from the Dezadeash Formation, Yukon, showing
1394 general compositional trends (sandstone=solid red line, mudstone=dashed red line) and
1395 Spearman rank correlation coefficients (r).
1396
1397 Figure. 13. Feldspar weathering diagram [A-CN-K ternary plot of molecular proportions of
1398 Al2O3-(CaO*+Na2O)-K2O] and Chemical Index of Alteration (CIA) of sandstone,
1399 mudstone and hemipelagite samples from the Dezadeash Formation, Yukon. CaO*=CaO
1400 associated only with silicates. Yellow field (top) indicates main range in CIA of sandstone
1401 samples; green field (middle) indicates main range in CIA of mudstone samples; and blue
1402 field (botton) indicates main range in CIA of hemipelagite samples. After Nesbitt and
1403 Young (1984), Fedo et al. (1995), Nesbitt (2003), and McLennan et al. (2003).
1404
1405 Figure. 14. Chondrite-normalized rare earth element diagrams of sandstones (A),
1406 mudstones (B) and hemipelagites (C) from the Dezadeash Formation, Yukon. D) Average
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1407 REE values for Upper Crust, Middle Crust, Total Crust, North American Shale Composite
1408 (NASC), Post Archean Australian Shale (PAAS), and Global Subducting Sediment
1409 (GLOSS) (from Gromet et al., 1984; Plank and Langmuir, 1998; McLennan, 2001; and
1410 Rudik and Gao, 2003). Normalizing values after Sun and McDonough (1989).
1411
1412 Figure. 15. Chemical classification diagram (Lu/Hf versus Sm/Nd) for sandstone
1413 (SANDSTN), mudstone (MUDSTN) and hemipelagite (HEMIPLG) samples from the
1414 Dezadeash Formation, Yukon. Classification after Hawkesworth et al. (2010). Most
1415 sandstone and mudstone samples plot within the field for turbidites and along the trend for
1416 magmatic differentiation.
1417
1418 Figure. 16. Chemical classification diagram (Th/Sc versus Zr/Sc) for sandstone
1419 (SANDSTN), mudstone (MUDSTN) and hemipelagite (HEMIPLG) samples from the
1420 Dezadeash Formation, Yukon. Classification after McLennan et al. (1993). Most sandstone
1421 and mudstone samples plot within the field for active margin turbidites and along the trend
1422 for compositional variations in the source area.
1423
1424 Figure. 17. Tectonic setting discrimination diagrams for samples from the Dezadeash
1425 Formation, Yukon. A) La versus Th diagram for sandstone (SANDSTN), mudstone
1426 (MUDSTN) and hemipelagite (HEMIPLG) samples. Classification after Bhatia and Crook
1427 (1986). B) Sc-Th-Zr/10 ternary diagram for sandstone (SANDSTN), mudstone (MUDSTN)
1428 and hemipelagite (HEMIPLG) samples. Classification after Bhatia and Crook (1986).
1429
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1430 Figure. 18. Tectonic setting discrimination histograms for sandstone (SANDSTN),
1431 mudstone (MUDSTN) and hemipelagite (HEMIPLG) samples from the Dezadeash
1432 Formation, Yukon. A) εNd (149) values. B) Eu/Eu* values. C) Th/Sc values. D) Th/U values.
1433 OUCC=Old Upper Continental Crust, RSR=Re-cycled Sedimentary Rocks, YDA=Young
1434 Differentiated Arc, YUA=Young Undifferentiated Arc. Classification after McLennan et al.
1435 (1993).
1436
1437 Figure. 19. εNd (o) vs. Age diagram for sandstone (SANDSTN), mudstone (MUDSTN) and
1438 hemipelagite (HEMIPLG) samples from the Dezadeash Formation, Yukon, compared to the
1439 Wrangellia composite terrane (specifically the Alexander and Wrangellia terranes), Yukon
1440 composite terrane (specifically the Yukon-Tanana, Kootenay, Cassiar, Quesnel, Cache
1441 Creek, Slide Mountain, and Stikine terranes), and Kluane Schist. DM=depleted mantle
1442 standard, CHUR=chondrite meteorite standard. After Samson et al. (1989, 1990, 1991),
1443 Farmer et al. (1993), Patchett and Gehrels (1998), Aleinikoff et al. (2000), Mezger et al.
1444 (2001), and Green et al. (2009).
1445
1446 Figure. 20. Possible tectonic settings for the Wrangellia composite terrane and the
1447 continental margin of Laurasia, and origin of the basin containing strata of the Gravina-
1448 Nutzotin belt (no horizontal or vertical scale implied). A) Precollisional, ocean basin
1449 scenario with east-dipping subduction beneath the WCT, east-dipping subduction beneath
1450 the accreted YCT margin, and an ocean of indeterminant width separating the WCT from
1451 the YCT (modified from Berg et al., 1972; Monger et al., 1982; Nokleberg et al., 1985; and
1452 Kapp and Gehrels, 1998); B) Syncollisional, retroarc foreland basin scenario with east-
1453 dipping subduction beneath the WCT and east-dipping subduction beneath the YCT, in
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1454 which the WCT is colliding progressively from the south to the north with the accreted
1455 YCT (modified from Trop et al., 2002; and Manuszak et al., 2007); C) Rift or
1456 transtensional basin scenario with east-dipping subduction beneath the WCT and a narrow
1457 ocean separating the WCT from the accreted YCT (modified from van der Heyden, 1992;
1458 McClelland et al., 1992; McClelland and Mattinson, 2000; and Yokelson et al., 2015); and
1459 D) Precollisional, forearc basin scenario, with west-dipping subduction beneath the WCT
1460 and a wide ocean separating the WCT from the accreted YCT (modified from Hildebrand,
1461 2013; and Sigloch and Mialynuk, 2017). Penecontemporaneous east-dipping subduction
1462 (dashed lines) may have occurred (Sigloch and Mialynuk, 2017).
1463
1464 Supplementary Figure Captions
1465
1466 Supplementary Figure. 1. Point-count classification of sandstones from the Dezadeash
1467 Formation, Yukon. Q-F-R ternary diagram. Classification after Folk et al. (1970). Q=total
1468 monocrystalline and polycrystalline quartz grains excluding chert, F=total feldspar grains,
1469 R=total plutonic, metamorphic, and sedimentary rock grains, including chert.
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Table 1. Lithofacies sampled in the Dezadeash Formation, Yukon, Canada (lithofacies classification after Pickering et al., 1989).
____________________________________________________________________________________________________________________________
Description Other Characteristics Interpretation Lithofacies Code ____________________________________________________________________________________________________________________________
Disorganized conglomerate clasts up to 3 cm long debris flow A1.1
Disorganized muddy conglomerate clasts up to 20 cm long debris flow A1.2
Disorganized gravelly mudstone limestone clasts up to 10.5 m long debris flow A1.2
Disorganized gravelly mudstone limestone clasts up to 10.5 m long debris flow A1.4
Normally graded conglomerate clasts up to 30 cm long, rare coquina beds hyperconcentrated density flow A2.3
Thick/medium-bedded, fine- to medium-grained sand, rare granules, hyperconcentrated density flow B1.1
disorganized sandstone rip-up clasts, small channels or scours
Very thick/thick-bedded fine-grained sand, locally tuffaceous concentrated density flow C2.1
sandstone-mudstone couplets
Thin-bedded sandstone-mudstone couplets very fine to fine-grained sand surge-like turbidity flow C2.3
Thick irregular siltstone and mudstone laminae - - - turbidity flow-surge D2.2
Structureless mudstone - - - turbidity flow-surge E1.1
Lime mudstone black, associated with lithofacies C and D settling of biogenic ooze G1.1
____________________________________________________________________________________________________________________________
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Table 2. Re-calculated pebble-count data,
Dezadeash Formation, Yukon, Canada
(PMQ=plutonic+metamorphic+quartz clats,
S=sedimentary clasts, V=volcanic clasts).
_________________________________________
Sample PMQ % S % V %
_________________________________________
GL-244 28 60 12
GL-250 5 11 84
GL-257 31.6 46.4 22
_________________________________________
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Table 3. K-Ar isotopic age of diorite pebble (sample GL-244), Dezadeash Formation,
Yukon, Canada.
______________________________________________________________________________
Material K, 40*
Ar, 40*
Ar/Total 40
Ar 40*
Ar/40
K K-Ar age
analysed % ppm Ma ± 2σ
______________________________________________________________________________
hornblende 0.513 0.005319 0.254 0.008691 144 ±4
concentrate,
-80/+200
mesh
______________________________________________________________________________
Constants used are λᵦ=4.962x10 -10
/year, (λ ₑ + λ' ₑ)=0.581x10 -10
/year, 40
K/K=1.193x10-4
g /g, and
σ equals one standard deviation. Analysis by Geochron Laboratories, Cambridge, Massachusetts.
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Table 4. Sandstone point-count catagories, Dezadeash Formation, Yukon, Canada.
_______________________________________________________________________
Quartz Qt=Qm+Qp
Qc=Qm+Qp+Lsc
Qm=monocrystalline
Qp=polycrystalline (not including chert)
Feldspar F=Fk+Fp
Fk=kspar (potassium)
Fp=plagioclase
Lithic L=Ls+Lm+Lv
sedimentary Ls=Lsc+Lsm+Lsl
Lsc=chert
Lsm=mudstone
Lsl=limestone, dolostone and fossils
metamorphic Lm=Lmp+Lms
Lmp=phyllite
Lms=schist
volcanic Lv=Lvv+Lvf+Lvm+Lvl
Lvv=vitric texture
Lvf=felsitic texture
Lvm=microlitic texture
Lvl=lathwork texture
_______________________________________________________________________
Other (not included in total): bio=biotite, cpx=clinopyroxene, hor=hornblende,
opx=orthopyroxene, sph=spene, zir=zircon and (1, 2, 3, etc.)=number of grains counted.
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Table 5. Calculated point-count data (percent), Dezadeash Formation, Yukon, canada.
Sample Lithofacies Qm Qp Fk Fp Lsc Lsm Lsl Lmp Lms Lvv Lvf Lvm Lvt TOTAL
GL-19-1 C2.1 15.27 2.99 7.49 33.23 0.30 0.00 0.00 0.30 0.00 0.00 24.85 0.90 14.67 100.00 334
GL-22-2 C2.1 13.72 4.42 3.95 34.19 1.16 0.23 1.86 0.00 0.23 0.00 36.51 0.00 3.72 100.00 430
GL-23-3 C2.1 1.86 1.17 0.93 23.31 1.17 0.23 0.23 0.00 0.23 0.00 16.08 5.59 49.18 100.00 429
GL-260-1 C2.1 9.26 2.31 0.69 14.12 1.62 0.00 6.48 0.00 0.00 0.00 18.29 3.70 43.52 100.00 432
GL-1-2 B1.1 10.21 5.41 1.80 15.62 5.71 0.00 4.20 0.00 0.30 0.00 38.14 6.31 12.31 100.00 333
GL-2-1 B1.1 21.43 6.85 1.49 10.42 0.00 0.00 0.30 0.00 0.00 0.00 57.14 0.30 2.08 100.00 336
GL-2-4 B1.1 5.36 1.79 6.25 15.18 0.30 0.00 5.06 0.00 0.00 0.00 55.65 3.57 6.85 100.00 336
GL-3-1 B1.1 5.72 2.71 5.72 12.05 0.00 0.00 2.71 0.00 0.00 0.00 62.35 4.22 4.52 100.00 332
GL-3-8 B1.1 4.33 2.79 3.41 15.17 1.24 0.00 3.72 0.00 0.00 0.00 63.47 2.48 3.41 100.00 323
GL-4-1 B1.1 9.52 0.89 4.46 30.36 4.17 0.30 2.08 0.00 0.30 0.00 27.38 8.63 11.90 100.00 336
GL-6-1 B1.1 4.83 2.72 2.42 16.01 4.83 2.11 5.74 0.00 0.30 0.00 32.33 6.34 22.36 100.00 331
GL-8-6 B1.1 5.72 2.41 2.11 30.42 3.01 1.20 4.82 0.00 0.30 0.00 31.33 10.24 8.43 100.00 332
GL-9-3 B1.1 4.78 4.48 2.09 14.63 2.69 1.79 4.48 0.00 0.30 0.00 27.16 8.96 28.66 100.00 335
GL-10-1 B1.1 8.66 3.28 3.28 21.19 1.49 0.30 3.88 0.00 0.60 0.00 34.33 14.33 8.66 100.00 335
GL-12-2 B1.1 3.63 2.42 3.63 31.42 2.11 0.30 4.83 0.00 0.00 0.00 25.68 12.99 12.99 100.00 331
GL-13-1 B1.1 10.78 5.69 4.49 25.75 0.60 0.30 0.30 0.00 0.60 0.00 39.52 2.69 9.28 100.00 334
GL-13-2 B1.1 2.10 1.80 3.00 21.32 1.20 0.90 1.80 0.00 0.30 0.00 28.23 9.01 30.33 100.00 333
GL-13-3 B1.1 2.39 1.79 1.49 11.64 1.79 1.19 3.28 0.00 0.60 0.00 37.91 7.16 30.75 100.00 335
GL-14A-1 B1.1 12.20 4.17 6.85 34.23 1.49 2.98 1.19 0.00 0.30 0.00 31.55 0.89 4.17 100.00 336
GL-14B-1 B1.1 2.69 1.79 0.00 20.90 0.90 2.39 0.60 0.00 0.30 0.00 29.85 8.36 32.24 100.00 335
GL-17-3 B1.1 2.69 2.39 1.19 20.00 2.99 0.90 2.99 0.00 0.00 0.00 31.64 5.67 29.55 100.00 335
GL-17-4 B1.1 6.57 4.18 2.99 15.22 2.99 0.60 4.78 0.00 0.30 0.00 29.25 6.87 26.27 100.00 335
GL-18-1 B1.1 13.13 1.19 8.96 24.48 0.60 0.60 1.79 0.00 0.30 0.00 34.03 0.30 14.63 100.00 335
GL-18-6 B1.1 3.87 0.89 0.89 18.15 2.08 0.00 0.89 0.00 0.00 0.00 32.44 5.95 34.82 100.00 336
GL-19-2 B1.1 2.56 1.63 0.47 15.15 1.86 0.23 1.17 0.00 0.00 0.00 26.11 2.56 48.25 100.00 429
GL-21B-2 B1.1 3.78 3.55 2.60 19.39 2.13 0.00 3.78 0.00 0.00 0.00 23.40 4.49 36.88 100.00 423
GL-23-1 B1.1 15.81 3.72 2.79 29.30 1.86 0.47 0.00 0.00 0.23 0.00 33.95 2.56 9.30 100.00 430
GL-24-2 B1.1 4.41 0.46 0.46 20.42 2.55 0.00 3.25 0.00 0.23 0.00 11.14 1.62 55.45 100.00 431
GL-25-2 B1.1 5.81 2.33 0.23 11.40 1.40 0.47 0.47 0.00 0.00 0.00 27.91 5.12 44.88 100.00 430
GL-25-5 B1.1 2.32 1.86 0.23 21.11 2.32 0.70 3.02 0.00 0.23 0.00 17.63 3.71 46.87 100.00 431
GL-201-4 B1.1 3.26 3.73 0.93 18.65 1.63 0.00 1.40 0.23 0.00 0.00 17.02 9.09 44.06 100.00 429
GL-219-1 B1.1 0.70 1.63 1.40 38.37 0.23 0.23 1.16 0.00 0.00 0.00 25.81 1.40 29.07 100.00 430
Sample: section number-sample number
Lithofacies: C2.1=classical thick bedded turbidite, B1.1=massive sandstone
Quatz grains: Qm=monocrystalline; Qp=polycrystalline (not including chert)
Feldspar grains: Fk=kspar (potassium), Fp=plagioclase
Lithic sedimentary grains: Lsc=chert, Lsm=mudstone, Lsl=limestone, dolostone and fossils
Lithic metamorphic grains: Lmp=phyllite. Lms=schist
Lithic volcanic grains: Lvv=vitric texture, Lvf=felsitic texture, Lvm=microlitic texture, Lvl=lathwork texture
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Table 6. Calculated lithogeochemical data, Dezadeash Formation, Yukon, Canada.
Sample Lithofacies ¹ CIA ² ICV ³ SiO2/Al2O3 Fe2O3/K2O Cr/Ni Cr/Th Cr/V La/Co La/Sc La/Y La/Yb Th/Co Th/Sc Th/U Y/Ni Zr/Sc ∑LREE ¹¹ ∑HREE ¹² ∑LREE/∑HREE ¹³ ∑REE ²¹ (Gd/Yb)N ²² (La/Lu)N ²³ (La/Sm)N ³¹ (La/Yb)N ³² Ce/Ce* ³³ Eu/Eu* ³³³
GL-2-3 conglomerate (A1.1) 47.48 1.49 3.61 3.93 2.33 22.36 0.39 1.22 0.94 0.76 8.08 0.16 1.66 1.60 0.77 6.17 79.39 13.64 5.82 94.30 1.28 5.61 2.48 5.46 0.91 0.98
GL-6-2 conglomerate (A1.1) 39.44 1.65 3.99 3.32 3.00 32.49 0.53 1.04 1.15 0.81 9.66 0.14 0.16 1.43 0.81 5.75 88.91 14.24 6.24 104.78 1.64 6.61 2.82 6.52 0.93 1.16
GL-3-5 pebbly sandstone (A1.4) 35.32 1.48 3.94 5.52 2.33 24.22 0.38 0.87 0.81 0.73 7.44 0.17 0.16 1.28 0.68 5.93 68.41 12.75 5.36 82.36 1.38 5.10 2.57 5.03 0.92 1.04
GL-9-4 pebbly sandstone (A1.4) 41.32 1.67 3.76 3.38 2.21 14.59 0.41 0.93 1.02 1.02 8.81 0.25 0.28 1.47 0.55 na na na na na na 6.04 4.09 5.95 na na
GL-3-3 pebbly sandstone (A1.4) 39.23 1.75 3.40 9.52 3.00 34.35 0.44 0.79 0.73 0.76 8.22 0.12 0.11 1.51 0.72 4.96 79.07 13.54 5.84 93.93 1.53 5.65 2.52 5.56 0.95 1.01
GL-12-1 pebbly sandstone (A1.4) 34.61 1.91 3.75 2.94 2.60 14.94 0.44 0.86 na 0.63 46.62 0.27 na 2.04 0.88 na 66.90 11.37 5.88 79.17 1.22 4.10 2.12 4.11 1.01 0.87
GL-6-4 pebbly sandstone (A1.4) 28.95 2.35 3.67 3.01 2.30 23.3 0.42 1.07 0.94 0.73 8.64 0.19 0.16 1.61 0.78 5.27 79.40 13.50 5.88 94.19 1.55 5.84 2.57 5.84 0.93 0.99
GL-4-8 pebbly sandstone (A1.4) 1.00 56.50 3.53 2.33 na na na 8.68 na 0.62 11.89 0.32 na 0.09 na na 29.43 4.94 5.94 34.69 1.45 7.46 4.17 8.04 1.05 0.72
GL-208-1 conglomerate (A2.3) 39.30 1.70 3.48 3.33 1.83 13.58 0.47 1.09 na 1.04 13.62 0.24 na 2.19 0.58 na 93.63 11.19 8.37 106.01 1.66 3.16 3.13 9.21 0.95 0.96
average 34.07 7.83 3.68 4.14 2.45 22.48 0.435 1.84 0.93 0.79 13.66 0.21 0.42 1.47 0.72 5.62 73.14 11.90 6.17 86.18 1.46 5.51 2.94 6.19 0.96 0.97
GL-1-5 sandstone (B1.1) 31.87 1.93 3.78 3.92 2.50 14.58 0.37 1.32 1.34 0.87 9.20 0.26 0.27 1.52 0.98 7.58 77.1 11.97 6.44 90.2 1.37 6.4 2.84 6.22 0.93 0.99
GL-2-1 sandstone (B1.1) 51.41 1.26 4.04 7.32 4.00 50.42 0.75 0.92 0.91 0.82 7.88 0.14 0.14 2.59 0.64 5.99 70.36 12.12 5.80 83.61 1.24 5.35 2.87 5.33 0.95 1.07
GL-2-4 sandstone (B1.1) 50.48 1.41 3.17 3.65 3.50 24.05 0.40 0.76 0.73 0.70 7.38 0.15 0.15 1.67 1.09 6.33 70.52 12.94 5.45 84.65 1.43 5.07 2.33 4.99 0.96 1.00
GL-3-1 sandstone (B1.1) 49.58 1.28 3.67 3.49 0.50 22.81 0.36 0.83 0.78 0.74 7.31 0.16 0.15 1.83 0.60 5.65 60.49 11.28 5.36 72.92 1.31 5.04 2.63 4.94 0.94 1.15
GL-4-1 sandstone (B1.1) 41.84 1.50 3.76 5.39 2.33 18.97 0.50 1.23 11.24 0.95 9.83 0.26 0.24 1.78 0.60 6.80 75.93 12.02 6.32 89.18 1.51 6.69 2.98 6.64 0.93 1.09
GL-6-1 sandstone (B1.1) 42.86 1.78 3.71 8.67 3.00 30.82 0.45 0.84 0.75 0.75 7.79 0.15 0.13 1.69 0.75 5.31 78.62 14.33 5.49 94.35 1.46 5.43 2.51 5.26 0.93 1.05
GL-8-6 sandstone (B1.1) 44.61 1.83 3.63 5.74 2.60 37.68 0.65 0.63 0.71 0.85 9.00 0.15 0.17 1.77 0.34 5.57 68.81 10.88 6.32 80.51 1.56 6.18 2.57 6.08 0.95 1.1
GL-9-3 sandstone (B1.1) 27.45 2.62 3.60 9.07 3.00 19.87 0.49 1.24 1.24 1.07 11.93 0.21 0.21 1.89 0.81 6.43 116.14 15.45 7.52 133.14 1.73 8.33 2.90 8.06 0.93 0.92
GL-10-1 sandstone (B1.1) 39.05 1.88 3.83 11.72 2.33 15.69 0.39 0.79 0.90 0.79 8.32 0.25 0.24 1.90 0.71 7.65 77.41 13.14 5.88 91.68 1.39 5.66 2.80 5.63 0.97 0.95
GL-12-2 sandstone (B1.1) 42.16 1.58 3.68 6.40 2.30 19.23 0.46 1.10 1.15 1.04 10.45 0.21 0.22 1.81 0.60 6.56 83.64 11.96 6.99 96.87 1.53 6.56 2.80 6.49 0.96 1.07
GL-13-2 sandstone (B1.1) 49.40 1.28 3.27 6.46 na 20.92 0.34 0.81 0.75 7.20 7.30 0.14 0.13 1.89 na 5.57 64.96 12.27 5.29 78.46 1.40 5.03 2.47 4.93 0.95 1.11
GL-17-4 sandstone (B1.1) 49.85 1.53 3.65 4.54 4.00 29.3 0.45 0.93 0.86 0.82 8.37 0.16 0.15 1.74 0.96 5.49 72.79 12.68 5.74 86-72 1.49 5.77 2.76 5.65 0.94 1.07
GL-19-2 sandstone (B1.1) 44.81 1.61 3.25 6.06 4.50 34.88 0.40 0.81 0.69 0.81 8.29 0.12 0.10 1.69 1.04 4.38 79.99 13.98 5.72 95.44 1.56 5.79 2.47 5.60 0.95 1.08
GL-20-1 sandstone (B1.1) 22.74 3.07 3.28 5.47 2.50 14.00 0.30 1.52 1.70 1.25 15.7 0.21 0.23 1.83 1.03 6.97 112.95 13.13 8.60 127.57 2.14 10.35 3.20 10.61 0.93 1.00
GL-20-3 sandstone (B1.1) 45.36 1.35 3.57 3.22 2.50 11.09 0.35 1.15 1.29 0.91 7.42 0.32 0.36 1.80 0.88 8.80 76.15 11.39 6.68 87.89 1.18 6.26 2.97 5.36 0.98 0.90
GL-25-1 sandstone (B1.1) 48.38 1.32 3.34 4.92 na 19.38 0.32 0.85 0.81 0.76 7.25 0.15 0.14 2.00 na 5.28 68.1 12.50 5.45 81.79 1.34 5.02 2.53 4.90 0.90 1.05
GL-25-5 sandstone (B1.1) 62.86 0.92 3.28 2.08 1.67 8.12 0.39 1.40 1.09 0.97 8.48 0.51 0.40 1.91 0.58 4.61 73.42 11.31 6.49 88.91 1.17 5.83 3.16 5.74 0.97 0.94
GL-400-3 sandstone (B1.1) 52.45 1.28 3.97 2.36 2.23 24.12 0.39 0.66 0.60 0.63 4.80 0.15 0.14 1.67 0.63 5.03 na na na na na 3.74 2.97 3.20 na na
GL-260-1 sandstone (C2.1) 46.55 1.27 3.16 6.64 1.83 33.86 0.47 0.60 na 0.73 8.32 0.10 na 2.19 0.43 na 51.51 8.76 5.88 61.22 1.47 5.36 2.39 5.62 0.96 1.12
GL-400-1 sandstone (C2.1) 48.67 1.34 3.32 6.95 2.19 19.32 0.28 0.79 0.78 0.83 7.13 0.14 0.14 1.56 0.77 5.47 na na na na na 5.15 3.29 4.85 na na
average 44.62 1.60 3.55 5.70 2.64 23.46 0.43 0.96 1.49 1.17 8.61 0.20 0.20 1.84 0.75 6.08 76.61 12.34 6.19 90.49 1.46 5.95 2.77 5.81 0.95 1.04
GL-12-5 mudstone (C2.3) 59.08 1.25 3.52 4.00 0.78 9.25 0.32 1.39 1.43 0.87 10.18 0.38 0.39 2.08 0.36 8.46 99.07 15.37 6.44 115.71 1.49 4.95 2.21 5.31 0.94 0.87
GL-16-1 mudstone (C2.3) 44.27 1.65 4.13 3.40 1.70 17.41 0.40 0.80 0.75 0.68 6.16 0.27 2.51 1.53 0.42 5.68 na na na na na 4.58 3.77 4.13 na na
GL-219-1 mudstone (C2.3) 45.89 1.37 3.33 10.6 2.00 46.62 0.43 0.66 na 0.75 7.11 0.10 na 2.06 0.37 na 49.57 9.94 4.99 60.49 1.46 4.68 2.41 4.80 0.90 1.10
GL-400-2 mudstone (C2.3) 64.92 1.52 3.65 4.52 1.62 26.06 0.45 0.92 0.76 0.76 6.25 0.17 0.14 2.58 0.44 4.70 na na na na na 4.56 3.53 4.22 na na
GL-400-4 mudstone (C2.3) 58.53 1.11 3.40 3.44 1.47 9.33 0.29 0.83 0.77 0.70 5.03 0.25 0.24 2.36 0.73 5.03 na na na na na 3.81 3.56 3.40 na na
GL-27-1 mudstone (D2.2) 52.97 1.19 3.73 5.53 5.50 46.6 0.74 0.78 0.71 0.59 5.78 0.15 0.13 2.05 1.07 na 60.47 13.28 4.55 74.9 1.22 3.78 2.35 3.90 0.95 1.05
average 54.28 1.35 3.63 5.25 2.18 25.88 0.44 0.90 0.88 0.73 6.75 0.22 0.68 2.11 0.57 5.97 69.70 12.86 5.33 83.70 1.39 4.39 2.97 4.29 0.93 1.01
GL-352-1 mudstone (E1.1) 68.66 0.76 6.60 2.36 1.66 9.71 0.16 0.78 0.07 0.09 0.38 2.00 0.17 1.14 0.71 7.39 na na na na na 0.22 1.09 0.24 na na
GL-1-3 hemipelagite (G1.1) 9.96 6.08 3.56 2.88 1.86 20.26 2.59 1.19 1.28 0.69 7.34 0.22 0.24 1.77 0.72 5.46 na na na na na 5.15 3.98 4.96 na na
GL-2-2 hemipelagite (G1.1) 31.87 4.26 3.07 2.00 1.52 28.08 0.41 1.53 1.40 0.72 7.90 0.11 0.10 1.86 1.04 3.18 na na na na na 5.22 4.57 5.29 na na
GL-3-2 hemipelagite (G1.1) 7.32 8.25 3.08 4.19 na 20.39 0.34 8.2 na 2.82 47.65 0.19 na 1.32 na na 67.42 9.03 7.47 77.66 1.5 29.77 16.12 32.22 0.83 1.47
GL-9-6 hemipelagite (G1.1) 4.70 12.23 3.25 1.73 1.11 11.54 0.40 3.55 3.63 1.49 16.02 0.31 0.32 2.6 1.11 9.27 na na na na na 10.30 6.40 10.83 na na
GL-12-4 hemipelagite (G1.1) 8.80 7.15 3.42 4.23 na 14.35 0.37 7.90 na 1.66 27.23 0.27 na 1.55 na na 186.61 16.22 11.5 204.79 1.61 16.14 7.54 18.39 0.83 1.18
average 12.53 7.59 3.28 3.01 1.50 18.92 0.82 4.47 2.10 1.48 21.23 0.22 0.22 1.82 0.96 5.97 127.02 12.63 9.49 141.23 1.56 13.32 7.72 14.34 0.83 1.33
Lithofacies ¹ = A1.1 (disorganized conglomerate), A1.4 (pebbly sandstone), A2.3 (graded conglomerate), (B1.1 (massive sandstone), C2.1 (thick bedded turbidite). C2.3 (thin bedded turbidite), D2.2 (thick bedded mudstone), E1.1 (structureless mudstone), G1.1 (lime mudstone)
CIA ² = 100[Al2O3/(Al2O3+Na2O+CaO*+K2O)], the Chemical Index of Alteration, where CaO* represents CaO associated only with silicates (Fedo et al., 1995).
ICV ³ = (Fe2O3+CaO+Na2O+K2O+MgO+MnO+TiO2/Al2O3), the Index of Compositional Variability (Cox et al., 1995).
∑LREE ¹¹ = ∑(La+Ce+Pr+Nd+Sm)
∑HREE ¹² =∑(Gd+Tb+Dy+Ho+Er+Tm+Yb+Lu)
∑LREE/∑HREE ¹³ =∑(La+Ce+Pr+Nd+Sm) /∑(Gd+Tb+Dy+Ho+Er+Tm+Yb+Lu)
∑REE ²¹ = ∑(La+Ce+Pr+Nd+Sm+Eu+Gd+Tb+Dy+Ho+Er+Tm+Yb+Lu)
(Gd/Yb)N ²² = , N=chondrite-normalized
(La/Lu)N ²³ = , N=chondrite-normalized
(La/Sm)N ³¹ = , N=chondrite-normalized
(La/Yb)N ³² = , N=chondrite-normalized
Ce/Ce* ³³ = CeN/[(LaN)(PrN)]½
, N=chondrite-normalized
Eu/Eu* ³³³ = EuN/[(SmN)(GdN)]½, N=chondrite-normalized
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Table 7. Sm-Nd isotopic data, Dezadeash Formation, Yukon, Canada. ____________________________________________________________________________________________________________________________________________________________________________________ Sample Lithology Sm Nd 147Sm/144Nd ±2σ 143Nd/144Nd ±2σ εNd(0)* εNd(149) ƒ Sm/Nd ̽ TDM(Ga)†
(ppm) (ppm)
____________________________________________________________________________________________________________________________________________________________________________________ GL-3-8 sandstone 3.73 18.05 0.12508 0.00013 0.512754 0.000005 +2.3 +3.5 -0.36 0.70 GL-4-8 sandstone 3.81 17.35 0.13262 0.00013 0.512660 0.000004 +0.4 +1.6 -0.33 0.94 GL-9-4 sandstone 3.86 18.03 0.12954 0.00013 0.512634 0.000007 +0.6 +1.9 -0.34 0.90 GL-18-6 sandstone 3.28 14.52 0.13566 0.00014 0.512815 0.000007 +3.4 +4.6 -0.30 0.69 GL-400-1 sandstone 3.91 17.26 0.13697 0.00014 0.512790 0.000005 +3.0 +4.1 -0.30 0.74 GL-400-3 sandstone 2.88 12.02 0.14460 0.00014 0.512788 0.000005 +2.9 +3.9 -0.26 0.82 GL-12-5 mudstone 6.85 31.80 0.13046 0.00013 0.512637 0.000005 0.0 +1.2 -0.34 0.96 GL-16-1 mudstone 3.95 17.69 0.13494 0.00013 0.512645 0.000005 +0.1 +0.1 -0.31 1.00 GL-352-1 mudstone 0.41 0.957 0.25791 0.00026 0.512852 0.000019 +4.2 +3.0 +0.31 na GL-400-2 mudstone 4.48 19.03 0.14226 0.00014 0.512738 0.000004 +1.9 +3.0 -0.28 0.9 GL-400-4 mudstone 4.39 18.67 0.14225 0.00014 0.512755 0.000006 +2.3 +3.3 -0.28 0.9 GL-1-3 hemipelagite 2.42 11.18 0.13087 0.00013 0.512472 0.000019 -3.2 -2.0 -0.33 1.27 GL-2-2 hemipelagite 2.73 12.99 0.12687 0.00013 0.512683 0.000011 +0.9 +2.2 -0.35 0.84 GL-3-2 hemipelagite 2.19 9.86 0.13442 0.00013 0.512658 0.000020 +0.4 +1.6 -0.32 0.97 GL-3-9 hemipelagite 3.34 16.37 0.12336 0.00012 0.512657 0.000019 +0.4 +1.8 -0.37 0.82 GL-9-6 hemipelagite 1.77 10.03 0.10669 0.00011 0.512634 0.000006 -0.1 +1.6 -0.46 0.75 GL-26-1 hemipelagite 3.07 13.40 0.13845 0.00014 0.512711 0.000007 +1.4 +2.5 -0.30 0.90
________________________________________________________________________________________________________________________________________________ *εNd(0)=(143Nd/144Ndmeas/
143Nd/144NdChur-1) x 104; present-day 143Nd/144NdChur=0.512638, normalized to 146Nd/144Nd=0.7219 (DePaolo and Wasserburg, 1976). ̽ ƒSm/Nd=[(147Sm/144Nd)meas/(
147Sm/144Nd)Chur]-1 (DePaolo, 1988). †TDM=(1/λ) x ln[(143Nd/144Ndmeas-
143Nd/144Ndmantle)/ (147Sm/144Ndmeas-
147Sm/144Ndmantle)+1] (DePaolo, 1981), with 143Nd/144Ndmantle=0.513163 and 147Sm/144Ndmantle=0.2138 (Goldstein et al., 1984).
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