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Journal Article

Closure of the Bangong–Nujiang Tethyan Ocean in the central Tibet: Results from the provenance of the Duoni Formation Available to Purchase

Zhicai Zhu, Qingguo Zhai, Peiyuan Hu, Sunlin Chung, Yue Tang, Haitao Wang, Hao Wu, Wei Wang, Zhiqiang Huang, Haoyang Lee
Published: 30 October 2019
Journal of Sedimentary Research (2019) 89 (10): 1039–1054.
DOI: https://doi.org/10.2110/jsr.2019.55
... segment of the Bangong–Nujiang suture zone, the Duoni Formation, consisting of a fluvial delta sequence with minor andesite interlayers, was originally defined as the Late Cretaceous Jingzhushan Formation and interpreted as the products of the Lhasa–Qiangtang collision during the Late Cretaceous. Our new...
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View PDF for article title, Closure of the Bangong–Nujiang Tethyan Ocean in the central Tibet: Results from the provenance of the <span class="search-highlight">Duoni</span> <span class="search-highlight">Formation</span>
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SITE-MEAN DIRECTIONS OF THE DUONI FORMATION RED BEDS FROM THE NAMUQIE AREA ... Available to Purchase

Published: 20 December 2022
TABLE 1. SITE-MEAN DIRECTIONS OF THE DUONI FORMATION RED BEDS FROM THE NAMUQIE AREA IN THE CENTRAL-EASTERN LHASA TERRANE
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Stepwise thermal demagnetization curves for the Duoni Formation red beds together with the reference data from Jiang et al. (2015). DRM—detrital remanent magnetization.

Stepwise thermal demagnetization curves for the Duoni Formation red beds to... Available to Purchase

Published: 20 December 2022
Figure 9. Stepwise thermal demagnetization curves for the Duoni Formation red beds together with the reference data from Jiang et al. (2015) . DRM—detrital remanent magnetization.
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LA-ICP-MS zircon U-Pb data of andesite interlayers in the Duoni Formation, ... Available to Purchase

Published: 30 October 2019
Table 1.— LA-ICP-MS zircon U-Pb data of andesite interlayers in the Duoni Formation, in the Beila area.
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Conglomerate clast counts for the Duoni Formation in the Beila area. Available to Purchase

Published: 30 October 2019
Table 2.— Conglomerate clast counts for the Duoni Formation in the Beila area.
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Heavy-mineral compositions of sandstone of the Duoni Formation, in the Beila area. a-20 (GPS Location: 31° 35′ 20.21″ N, 91° 19′ 32.59″ E); a-21 (GPS Location: 31° 35′ 22.94″ N, 91° 22′ 12.87″ E); 17TP7-1 (GPS Location: 90° 59′ 51.66″ E, 31° 23′ 7.25″ N); 17T229 (GPS Location: 90° 59′ 51.66″ E, 31° 23′ 7.25″ N). The coordinate system used: WGS84.

Heavy-mineral compositions of sandstone of the Duoni Formation, in the Beil... Available to Purchase

Published: 30 October 2019
Fig. 8.— Heavy-mineral compositions of sandstone of the Duoni Formation, in the Beila area. a-20 (GPS Location: 31° 35′ 20.21″ N, 91° 19′ 32.59″ E); a-21 (GPS Location: 31° 35′ 22.94″ N, 91° 22′ 12.87″ E); 17TP7-1 (GPS Location: 90° 59′ 51.66″ E, 31° 23′ 7.25″ N); 17T229 (GPS Location: 90° 59
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Measured sedimentary logs of the Duoni Formation in the Beila area. See Figure 1B for the location of measured sections. Pie charts represent components of conglomerates. Paleocurrent data (black rose diagram) are from cross-stratification, after DeCelles et al. (1983).

Measured sedimentary logs of the Duoni Formation in the Beila area. See Fi... Available to Purchase

Published: 30 October 2019
Fig. 2.— Measured sedimentary logs of the Duoni Formation in the Beila area. See Figure 1 B for the location of measured sections. Pie charts represent components of conglomerates. Paleocurrent data (black rose diagram) are from cross-stratification, after DeCelles et al. (1983) .
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Point-counting parameters of sandstones from the Duoni Formation in the Bei... Available to Purchase

Published: 30 October 2019
Table 3.— Point-counting parameters of sandstones from the Duoni Formation in the Beila area.
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Ternary diagrams for sandstones of the Duoni Formation, in the Beila area.

Ternary diagrams for sandstones of the Duoni Formation, in the Beila area. ... Available to Purchase

Published: 30 October 2019
Fig. 9.— Ternary diagrams for sandstones of the Duoni Formation, in the Beila area. Qt-F-L, Qm-F-Lt, and Qp-Lvm-Lsm diagrams after Dickinson (1982) , Lvf-Lvmi-Lvl diagram after Marsaglia and Ingersoll (1992) .
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Photographs of typical Duoni Formation outcrops in Mulong and Lalong villages of the Beila area (measured sections b–e; see Fig. 1B for location): A) the Duoni Formation conglomerate parallel-unconformably overlies the Middle–Late Jurassic Lagongtang Formation turbidites (GPS location: 31° 17′ 23.246″ N, 91° 7′ 11.365″ E). B) Thick pebble- and granule-bearing coarse sandstone bodies with planar and trough cross-bedding (GPS location: 31° 17′ 29.342″ N, 91° 7′ 6.409″ E). C) Lenticular conglomerate with sharp scouring base surface and trough cross-bedding (GPS location: 31° 23′ 23.472″ N, 91° 1′ 28.306″ E). D) Fluvial sandstone–siltstone/mudstone dual sequences of the lower section d. (GPS location: 31° 23′ 16.646″ N, 91° 2′ 16.681″ E). E) Lenticular conglomerates and pebble- and granule-bearing coarse sandstone in red medium–coarse sandstone, where some strata were locally deformed and trough and planar cross-bedding was developed (GPS location: 31° 23′ 57.384″ N, 91° 1′ 29.503″ E). F) Conglomerate contains andesite, basalt, gabbro, and sandstone (GPS location: 31° 24′ 44.70″ N, 91° 2′ 48.97″ E). G) Fault contact between the Beila ophiolite and the Duoni Formation (top of section d, GPS location: 31° 24′ 40.425″ N, 91° 2′ 53.989″ E). H) Andesite interlayered with the red sandstone at the lower section d (GPS location: 31° 23′ 30.94″ N, 91° 2′ 9.12″ E). The inset figure shows the photomicrograph of the andesite interlayer sample. Andesite displays a porphyritic structure with phenocrysts of plagioclase (∼ 40 vol. %) and amphibole (∼ 10 vol.%). Plagioclase has a great disparity in sizes and generally shows kaolinization and sericitization. The matrix is composed mainly of microlitic feldspar. I) Clear boundary between the red sandstone and andesite interlayers from the lower section d (GPS location: 31° 23′ 30.94″ N, 91° 2′ 9.12″ E). The coordinate system used: WGS84.

Photographs of typical Duoni Formation outcrops in Mulong and Lalong villag... Available to Purchase

Published: 30 October 2019
Fig. 4.— Photographs of typical Duoni Formation outcrops in Mulong and Lalong villages of the Beila area (measured sections b–e; see Fig. 1 B for location): A) the Duoni Formation conglomerate parallel-unconformably overlies the Middle–Late Jurassic Lagongtang Formation turbidites (GPS
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Photomicrographs of sandstone from the Duoni Formation, in the Beila area: A) sandstone from middle section a (GPS location: 31° 35′ 17.258″ N, 91° 21′ 30.342″ E). B) Sandstone from lower section b (GPS location: 31° 17′ 23.857″ N, 91° 7′ 11.235″ E). C) Sandstone from lower section c (GPS location: 31° 25′ 15.804″ N, 91° 12′ 19.334″ E). D) Sandstone from middle section d (GPS location: 31° 23′ 30.05″ N, 91° 2′ 7.31″ E). Qm, monocrystalline quartz; Qp, polycrystalline quartz; Pl, plagioclase feldspar; Kf, potassium feldspar; Lvf, felsic volcanic grains; Lvmi, mafic volcanic grains; Lvl, lathwork volcanic grains; Lvv, vitric volcanic grains; Lsi, siltstone lithic fragment; Lsa, argillite shale lithic; Lsch, chert lithic; Lc, carbonate lithic grains; Lmv, metamorphic volcanic lithic fragment; Lms, metamorphic sedimentary lithic fragment. The coordinate system used: WGS84.

Photomicrographs of sandstone from the Duoni Formation, in the Beila area: ... Available to Purchase

Published: 30 October 2019
Fig. 7.— Photomicrographs of sandstone from the Duoni Formation, in the Beila area: A) sandstone from middle section a (GPS location: 31° 35′ 17.258″ N, 91° 21′ 30.342″ E). B) Sandstone from lower section b (GPS location: 31° 17′ 23.857″ N, 91° 7′ 11.235″ E). C) Sandstone from lower section
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Photographs of typical Duoni Formation outcrops in the Namuqie Village of the Beila area (measured section a; see Fig. 1B for location): A) siltstone–mudstone layers of the lower succession of measured section a (GPS location: 31° 35′ 15.993″ N, 91° 19′ 16.549″ E). B) Sandstone with abundant cross-bedding of the middle succession of measured section a (GPS location: 31° 35′ 2.318″ N, 91° 20′ 37.872″ E). C) Conglomerate and sandstone layers of the upper succession of measured section a (GPS location: 31° 35′ 19.064″ N, 91° 22′ 10.502″ E). D) Red coarse- and medium-grained sandstone with large- and middle-scale planar and trough cross-bedding (GPS location: 31° 34′ 42.481″ N, 91° 21′ 21.652″ E). E) Asymmetric ripple marks in red medium-grained sandstones (GPS location: 31° 34′ 47.531″ N, 91° 21′ 24.614″ E). F) Climbing-ripple cross-lamination in red fine-grained sandstones (GPS location: 31° 35′ 32.413″ N, 91° 22′ 23.514″ E). G) Mud cracks (GPS location: 31° 35′ 32.735″ N, 91° 22′ 23.821″ E). H) Uneven base scouring surface and overlying flat bedding, planar and trough cross-bedding (GPS location: 31° 35′ 12.827″ N, 91° 22′ 25.711″ E). The coordinate system used: WGS84.

Photographs of typical Duoni Formation outcrops in the Namuqie Village of t... Available to Purchase

Published: 30 October 2019
Fig. 3.— Photographs of typical Duoni Formation outcrops in the Namuqie Village of the Beila area (measured section a; see Fig. 1 B for location): A) siltstone–mudstone layers of the lower succession of measured section a (GPS location: 31° 35′ 15.993″ N, 91° 19′ 16.549″ E). B) Sandstone
Journal Article

Location and shape of the Lhasa terrane prior to India-Asia collision Available to Purchase

Weiwei Bian, Suo Wang, Yong Yao, Xianwei Jiao, Wenxiao Peng, Tianshui Yang, Shihong Zhang, Huaichun Wu, Haiyan Li, Chenglong Deng
Journal: GSA Bulletin
Published: 20 December 2022
GSA Bulletin (2023) 135 (9-10): 2255–2274.
DOI: https://doi.org/10.1130/B36647.1
...TABLE 1. SITE-MEAN DIRECTIONS OF THE DUONI FORMATION RED BEDS FROM THE NAMUQIE AREA IN THE CENTRAL-EASTERN LHASA TERRANE ...
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Stratigraphy and facies comparison among Cretaceous basins on the northern Lhasa terrane. Data sources: Duoni Formation in Baingoin Basin (Lai et al., 2019a) and Selin Co Basin (Zhang et al., 2011); Duoni Formation and Zenong Group in Coqen Basin (Sun et al., 2015a, 2017); Tangza Formation in Gegyai area (Ye et al., 2019).

Stratigraphy and facies comparison among Cretaceous basins on the northern ... Available to Purchase

Published: 11 May 2021
Figure 10. Stratigraphy and facies comparison among Cretaceous basins on the northern Lhasa terrane. Data sources: Duoni Formation in Baingoin Basin ( Lai et al., 2019a ) and Selin Co Basin ( Zhang et al., 2011 ); Duoni Formation and Zenong Group in Coqen Basin ( Sun et al., 2015a , 2017
Book Chapter

Early Cretaceous Gangdese retroarc foreland basin evolution in the Selin Co basin, central Tibet: evidence from sedimentology and detrital zircon geochronology Available to Purchase

Author(s)
Qing-Hai Zhang, Lin Ding, Fu-Long Cai, Xiao-Xia Xu, Li-Yun Zhang, Qiang Xu, Helmut Willems
Book: Growth and Collapse of the Tibetan Plateau
Series: Geological Society, London, Special Publications
Publisher: Geological Society of London
Published: 01 January 2011
DOI: 10.1144/SP353.3
EISBN: 9781862396012
... in zircon grains with the age of 125–140 and 160–180 Ma, and the Duoni Formation was dominated by one main age cluster of 125–150 Ma. Analysis of the potential provenances suggests the Early Cretaceous zircon grains were primarily derived from the Gangdese magmatic arc to the south. The youngest zircon ages...
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Abstract
View PDF for content titled, Early Cretaceous Gangdese retroarc foreland basin evolution in the Selin Co basin, central Tibet: evidence from sedimentology and detrital zircon geochronology
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Abstract The Selin Co basin in the northern Lhasa terrane includes more than 3000 m of upward coarsening Lower Cretaceous strata, and the sedimentary sequence from the flysch to the molasse indicates the evolution of a foreland basin. Petrographic analysis shows that sandstones are rich in volcanic and sedimentary lithics and most of them fall into recycled orogen and magmatic arc. Uranium–lead (U–Pb) ages were determined for 435 detrital zircons from the Lower Cretaceous strata in the Selin Co basin. Relative probability of detrital zircon ages shows the Eshaerbu Formation was rich in zircon grains with the age of 125–140 and 160–180 Ma, and the Duoni Formation was dominated by one main age cluster of 125–150 Ma. Analysis of the potential provenances suggests the Early Cretaceous zircon grains were primarily derived from the Gangdese magmatic arc to the south. The youngest zircon ages in the lowermost exposure of the Eshaerbru Formation are c . 130 Ma, providing a maximum depositional age of sediments in the Selin Co basin. Collectively, our studies, together with previously documented Cretaceous thrusting in the Lhasa terrane, suggest the Lower Cretaceous Selin Co basin was deposited in a retroarc foreland basin. From 145–90 Ma, a retroarc foreland basin was presumed to develop in the Lhasa terrane, migrating from the south to the north. Crustal thickening, likely associated with the evolution of the retroarc foreland basin, was speculated to start in the Early Cretaceous in the Lhasa terrane.

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ANISOTROPY OF ISOTHERMAL REMANENT MAGNETIZATION (IRM) OF THE DUONI FORMATIO... Available to Purchase

Published: 20 December 2022
TABLE 2. ANISOTROPY OF ISOTHERMAL REMANENT MAGNETIZATION (IRM) OF THE DUONI FORMATION RED BEDS
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Zircon U-Pb concordia diagrams and histograms for sandstones from the Duoni Formation, in the Beila area.

Zircon U-Pb concordia diagrams and histograms for sandstones from the Duoni... Available to Purchase

Published: 30 October 2019
Fig. 6.— Zircon U-Pb concordia diagrams and histograms for sandstones from the Duoni Formation, in the Beila area.
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Zircon U-Pb concordia diagrams for andesite interlayers from the Duoni Formation, in the Beila area.

Zircon U-Pb concordia diagrams for andesite interlayers from the Duoni Form... Available to Purchase

Published: 30 October 2019
Fig. 5.— Zircon U-Pb concordia diagrams for andesite interlayers from the Duoni Formation, in the Beila area.
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(A–F) Photographs showing field outcrops of the Lower Cretaceous Duoni Formation red beds of section A (A–C) and section B (D–F) in the Namuqie area.

(A–F) Photographs showing field outcrops of the Lower Cretaceous Duoni Form... Available to Purchase

Published: 20 December 2022
Figure 2. (A–F) Photographs showing field outcrops of the Lower Cretaceous Duoni Formation red beds of section A (A–C) and section B (D–F) in the Namuqie area.
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Typical demagnetization trajectories of representative specimens from the Lower Cretaceous Duoni Formation red beds in the Namuqie area. NRM—natural remanent magnetization. The directions of remanence are all in geographic coordinates. Solid (open) symbols represent projections onto the horizontal (vertical) plane.

Typical demagnetization trajectories of representative specimens from the L... Available to Purchase

Published: 20 December 2022
Figure 5. Typical demagnetization trajectories of representative specimens from the Lower Cretaceous Duoni Formation red beds in the Namuqie area. NRM—natural remanent magnetization. The directions of remanence are all in geographic coordinates. Solid (open) symbols represent projections onto