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Journal Article

Coupling of rock uplift and river incision in the Namche Barwa–Gyala Peri massif, Tibet Available to Purchase

Noah J. Finnegan, Bernard Hallet, David R. Montgomery, Peter K. Zeitler, John O. Stone, Alison M. Anders, Liu Yuping
Journal: GSA Bulletin
Published: 01 January 2008
GSA Bulletin (2008) 120 (1-2): 142–155.
DOI: https://doi.org/10.1130/B26224.1
... of the Namche Barwa–Gyala Peri massif, an active antiformal structure within the eastern Himalayan syntaxis. Our rich and dense data set reveals a tight spatial correspondence of fluvial incision potential, high relief, and young cooling ages. The spatial coincidence is most easily explained by a sustained...
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View PDF for article title, Coupling of rock uplift and river incision in the <span class="search-highlight">Namche</span> <span class="search-highlight">Barwa</span>–Gyala Peri <span class="search-highlight">massif</span>, Tibet
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Modeled development processes for the Namche Barwa massif. a, Progressive accelerating. b, Impulsive accelerating. For details, refer to the text.

Modeled development processes for the Namche Barwa massif. a , Progressive... Available to Purchase

Published: 01 September 2015
Figure 7. Modeled development processes for the Namche Barwa massif. a , Progressive accelerating. b , Impulsive accelerating. For details, refer to the text.
Image
a, Compilation of exhumation rates of the Namche Barwa massif. Bars show average values and ranges of exhumation rates, computed on the basis of ages from the thermochronometries of monazite Th-Pb, hornblende 40Ar/39Ar, zircon and apatite fission track, and zircon (U-Th)/He. Black squares show exhumation rates calculated from biotite 40Ar/39Ar ages. Temperature distribution pattern is from Craw et al. (2005). Geothermal gradient values were averaged in grids of 15′ by 15′. b, Estimations of the exhumation thickness of the syntaxial core (zone A in fig. 4). Bars show average values and ranges of the exhumation rates at different stages.

a , Compilation of exhumation rates of the Namche Barwa massif. Bars show a... Available to Purchase

Published: 01 September 2015
Figure 8. a , Compilation of exhumation rates of the Namche Barwa massif. Bars show average values and ranges of exhumation rates, computed on the basis of ages from the thermochronometries of monazite Th-Pb, hornblende 40 Ar/ 39 Ar, zircon and apatite fission track, and zircon (U-Th)/He. Black
Journal Article

Tectonics, exhumation, and drainage evolution of the eastern Himalaya since 13 Ma from detrital geochemistry and thermochronology, Kameng River Section, Arunachal Pradesh Available to Purchase

François Chirouze, Pascale Huyghe, Peter van der Beek, Catherine Chauvel, Tapan Chakraborty, Guillaume Dupont-Nivet, Matthias Bernet
Journal: GSA Bulletin
Published: 01 March 2013
GSA Bulletin (2013) 125 (3-4): 523–538.
DOI: https://doi.org/10.1130/B30697.1
... less negative ε Nd and ε Hf values that require involvement of the Gangdese Batholith and Yarlung suture zone source areas via the Brahmaputra River system. Consequently, these sediments should also record incision of the Namche Barwa massif by this river. Source-area exhumation rates of Himalayan...
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View PDF for article title, Tectonics, exhumation, and drainage evolution of the eastern Himalaya since 13 Ma from detrital geochemistry and thermochronology, Kameng River Section, Arunachal Pradesh
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Journal Article

Early onset and late acceleration of rapid exhumation in the Namche Barwa syntaxis, eastern Himalaya Open Access

Gwladys Govin, Peter van der Beek, Yani Najman, Ian Millar, Lorenzo Gemignani, Pascale Huyghe, Guillaume Dupont-Nivet, Matthias Bernet, Chris Mark, Jan Wijbrans
Journal: Geology
Published: 21 July 2020
Geology (2020) 48 (12): 1139–1143.
DOI: https://doi.org/10.1130/G47720.1
... prominently in the debate on tectonic versus erosional forcing of exhumation. Both the mechanism and timing of rapid exhumation of the Namche Barwa massif in the eastern syntaxis remain controversial. It has been argued that coupling between crustal rock advection and surface erosion initiated in the late...
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View PDF for article title, Early onset and late acceleration of rapid exhumation in the <span class="search-highlight">Namche</span> <span class="search-highlight">Barwa</span> syntaxis, eastern Himalaya
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(A) Topography, active faults (white), and major rivers (blue) of the Himalaya. Triangles show syntaxial massifs: NP—Nanga Parbat; NB—Namche Barwa. Box shows location of panel B. IYSZ—Indus-Yarlung suture zone. (B) Eastern syntaxis, showing Namche Barwa massif, Yigong, Parlung, and Yarlung-Tsangpo-Siang-Brahmaputra Rivers, and sampling locations. Stars indicate sampled sections; black lines show major faults. Orange and purple dashed lines are contours of zircon fission-track–zircon (U-Th)/He (ZFT/ZHe) and biotite 40Ar/39Ar cooling ages &lt;2 Ma, respectively (Gemignani et al., 2018). NB—Namche Barwa; GP—Gyala Peri; NLT—Nam La thrust; RUPb—rutile U-Pb age.

(A) Topography, active faults (white), and major rivers (blue) of the Himal... Open Access

Published: 21 July 2020
Figure 1. (A) Topography, active faults (white), and major rivers (blue) of the Himalaya. Triangles show syntaxial massifs: NP—Nanga Parbat; NB—Namche Barwa. Box shows location of panel B. IYSZ—Indus-Yarlung suture zone. (B) Eastern syntaxis, showing Namche Barwa massif, Yigong, Parlung
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A: Detrital zircon U-Pb crystallization age probability density functions (black lines) and kernel density estimates (gray) characterize two primary sources: Tibetan zircons are younger than 250 Ma, shown in the Tibetan tributaries flowing into Tsangpo Gorge (compiled from this study and Zhang et al., 2012); and gorge-derived Himalayan zircons are typically ca. 500 Ma, with small component of &lt;30 Ma anatectic grains from the western side of Namche Barwa massif (Booth et al., 2004), shown in both a detrital sample from a small west-draining cirque and compiled bedrock ages from Namche Barwa massif (gray histogram from Booth et al., 2004; Zhang et al., 2012; n = 325). Inset bar shows proportion of young (&lt;30 Ma) anatectic zircons sourced only from Namche Barwa (black) with U/Th of &gt;10, and young igneous zircons (white) with U/Th of &lt;10. Himalayan-age zircons in modern sediment downstream of Tsangpo Gorge (compiled from this study; Stewart et al., 2008; Cina et al., 2009) demonstrate the addition of zircons eroded from the gorge, including a few young anatectic grains. A.D. 2000 flood deposits show a similar proportion of gorge-derived zircons, with slightly fewer anatectic grains. Megaflood deposits contain a much higher proportion of Himalayan zircons and anatectic grains sourced only from Namche Barwa, indicating extreme focusing of erosion in the gorge by megafloods. Sample numbers refer to locations in Figure 1. B: Petrographic analyses of flood sediments rule out local sources for the deposits and confirm a mixed provenance between Himalayan and Tibetan sources (Himalayan and Tibetan source data from Zhang et al., 2012; Garzanti et al., 2004). Q—quartz; F—feldspar; L—lithics.

A: Detrital zircon U-Pb crystallization age probability density functions (... Available to Purchase

Published: 01 September 2013
and Zhang et al., 2012 ); and gorge-derived Himalayan zircons are typically ca. 500 Ma, with small component of <30 Ma anatectic grains from the western side of Namche Barwa massif ( Booth et al., 2004 ), shown in both a detrital sample from a small west-draining cirque and compiled bedrock ages from
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Detrital zircon fission-track cooling ages from Upper and Middle Siwalik samples compared to ages from modern Siang River samples (Enkelmann et al., 2011). U-Pb dating of the same Upper and Middle Siwalik zircons permits differentiation of cooling ages by source region. Pie charts indicate the percentages of Himalayan zircons with crystallization ages older than 300 Ma and Transhimalayan zircons younger than 300 Ma. Only Himalayan zircons are illustrated in line plots. Young cooling age components attributed to the Namche Barwa massif (Enkelmann et al., 2011) persist in young lag times of Upper and Middle Siwalik samples until 25c and 5b. Sample 5b is dominated by zircons with a Transhimalayan U-Pb age provenance, which may reflect erosion of the suture zone and Transhimalaya intrusive units prior to exhumation of the Namche Barwa massif. Fission-track age components (white boxes) were determined with the DensityPlotter application of Vermeesch (2012). The total number of analyses (nall) and number of zircons with U-Pb ages older than 300 Ma (n300) are reported. Plots include area normalized, summed probability density functions (PDF, thin black lines) , and kernel density estimates (KDE, thick gray lines).

Detrital zircon fission-track cooling ages from Upper and Middle Siwalik sa... Available to Purchase

Published: 01 September 2016
indicate the percentages of Himalayan zircons with crystallization ages older than 300 Ma and Transhimalayan zircons younger than 300 Ma. Only Himalayan zircons are illustrated in line plots. Young cooling age components attributed to the Namche Barwa massif ( Enkelmann et al., 2011 ) persist in young lag
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A: Location of Yarlung-Tsangpo River (Tibetan Plateau). Where the river turns southward and plunges from the Tibetan Plateau through the Tsangpo Gorge, it begins to erode Himalayan source rocks of the Namche Barwa massif (NB) (Booth et al., 2009; Zhang et al., 2012). B: Relict glacial dams upstream of Tsangpo Gorge record impoundment of massive Quaternary lakes (Montgomery et al., 2004; Chen et al., 2008; Korup and Montgomery, 2008), which catastrophically drained through the gorge. An A.D. 2000 landslide impounded the Yigong River, a tributary to the gorge; failure of the landslide dam released an analogous smaller-magnitude flood through the gorge. C: We sampled megaflood and 2000 flood slackwater deposits downstream of the gorge (adapted from Montgomery et al., 2004; Finnegan et al., 2008; Larsen and Montgomery, 2012), and modern river sediment samples (locations 3, 5–8) throughout the watershed where previously published data (locations 1, 2, 4, 12 from Stewart et al., 2008; Cina et al., 2009; Zhang et al., 2012) did not exist. Sample 5 is from a small cirque draining the western Namche Barwa massif; a.s.l.—above sea level.

A: Location of Yarlung-Tsangpo River (Tibetan Plateau). Where the river tur... Available to Purchase

Published: 01 September 2013
Figure 1. A: Location of Yarlung-Tsangpo River (Tibetan Plateau). Where the river turns southward and plunges from the Tibetan Plateau through the Tsangpo Gorge, it begins to erode Himalayan source rocks of the Namche Barwa massif (NB) ( Booth et al., 2009 ; Zhang et al., 2012 ). B: Relict
Image
(A) Map of the study area showing the Indus-Yarlung suture zone (IYSZ; dashed line) and rivers surrounding the eastern Himalayan syntaxis. The Yarlung River turns southward around the Namche Barwa massif (NB, 7782 m peak elevation), to join the Brahmaputra River in the Himalayan foreland basin (yellow area). (B) The Tsangpo Gorge (red line) bisects the Namche Barwa massif (purple area from Zeitler et al., 2014), a source of anomalously young cooling ages (pink area encompasses zircon fission-track ages younger than 3 Ma and biotite 40Ar/39Ar ages younger than 10 Ma (see text for data references). Black squares indicate sample locations for modern detrital white mica from the Siang River (A, B, C) and Himalayan tributaries (X, Y, Z). Red boxes outline sections studied by us (see Figs. 2 and 3) and by Chirouze et al. (2012a). Basin depth contours are from Verma and Mukhopadhyay (1977). Structure abbreviations: MCT—Main Central thrust; MFT—Main Frontal thrust; MBT—Main Boundary thrust; STD—South Tibetan detachment; TPT—Tipi thrust; NT—Naga thrust; MT—Mishmi thrust. Contacts are compiled from Armijo et al. (1989); Agarwal et al. (1991); Baruah et al. (1992); Pan et al. (2004); Acharyya (2007); Misra (2009); Yin et al. (2010); and Zeitler et al. (2014).

(A) Map of the study area showing the Indus-Yarlung suture zone (IYSZ; dash... Available to Purchase

Published: 01 September 2016
Figure 1. (A) Map of the study area showing the Indus-Yarlung suture zone (IYSZ; dashed line) and rivers surrounding the eastern Himalayan syntaxis. The Yarlung River turns southward around the Namche Barwa massif (NB, 7782 m peak elevation), to join the Brahmaputra River in the Himalayan
Journal Article

Erosion of the Tsangpo Gorge by megafloods, Eastern Himalaya Available to Purchase

Karl A. Lang, Katharine W. Huntington, David R. Montgomery
Journal: Geology
Published: 01 September 2013
Geology (2013) 41 (9): 1003–1006.
DOI: https://doi.org/10.1130/G34693.1
... and Zhang et al., 2012 ); and gorge-derived Himalayan zircons are typically ca. 500 Ma, with small component of <30 Ma anatectic grains from the western side of Namche Barwa massif ( Booth et al., 2004 ), shown in both a detrital sample from a small west-draining cirque and compiled bedrock ages from...
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Journal Article

Constraints on the metamorphic evolution of the eastern Himalayan syntaxis from geochronologic and petrologic studies of Namche Barwa Available to Purchase

Amanda L. Booth, C. Page Chamberlain, William S.F. Kidd, Peter K. Zeitler
Journal: GSA Bulletin
Published: 01 March 2009
GSA Bulletin (2009) 121 (3-4): 385–407.
DOI: https://doi.org/10.1130/B26041.1
...Amanda L. Booth; C. Page Chamberlain; William S.F. Kidd; Peter K. Zeitler Abstract The eastern Himalayan syntaxis is host to the actively deforming metamorphic massif, Namche Barwa. This massif has experienced a complex history of uplift and deformation, influenced by intense fluvial erosion...
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View PDF for article title, Constraints on the metamorphic evolution of the eastern Himalayan syntaxis from geochronologic and petrologic studies of <span class="search-highlight">Namche</span> <span class="search-highlight">Barwa</span>
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Geologic sketch map of Namche Barwa–Gyala Peri massif and the Brahmaputra canyon (Pan et al., 2004, with modifications courtesy of W.S.F. Kidd). Black squares are locations of detrital sand samples. Circles represent bedrock zircon (U-Th)/He cooling ages; diamonds represent bedrock 40Ar/39Ar biotite cooling ages (Malloy, 2004). Green line is contour for zircon (U-Th)/He ages younger than 2 Ma, and red line is contour for 40Ar/39Ar biotite ages younger than 2 Ma.

Geologic sketch map of Namche Barwa–Gyala Peri massif and the Brahmaputra c... Available to Purchase

Published: 01 September 2008
Figure 1. Geologic sketch map of Namche Barwa–Gyala Peri massif and the Brahmaputra canyon ( Pan et al., 2004 , with modifications courtesy of W.S.F. Kidd). Black squares are locations of detrital sand samples. Circles represent bedrock zircon (U-Th)/He cooling ages; diamonds represent bedrock
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Figure 2. Spatial distribution of zircon (U-Th)/He ages in the vicinity of the Namche Barwa–Gyala Peri massif. Stars denote the locations of Namche Barwa and Gyala Peri.

Figure 2. Spatial distribution of zircon (U-Th)/He ages in the vicinity of ... Available to Purchase

Published: 01 January 2008
Figure 2. Spatial distribution of zircon (U-Th)/He ages in the vicinity of the Namche Barwa–Gyala Peri massif. Stars denote the locations of Namche Barwa and Gyala Peri.
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Figure 3. Spatial distribution of biotite 40Ar/39Ar ages in the vicinity of the Namche Barwa–Gyala Peri massif. Stars denote the locations of Namche Barwa and Gyala Peri.

Figure 3. Spatial distribution of biotite 40 Ar/ 39 Ar ages in the vicinit... Available to Purchase

Published: 01 January 2008
Figure 3. Spatial distribution of biotite 40 Ar/ 39 Ar ages in the vicinity of the Namche Barwa–Gyala Peri massif. Stars denote the locations of Namche Barwa and Gyala Peri.
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Figure 6. Patterns in mean annual river power in the vicinity of the Namche Barwa–Gyala Peri massif. Areas with no data coverage were not included in the analysis. Stars denote the locations of Namche Barwa and Gyala Peri.

Figure 6. Patterns in mean annual river power in the vicinity of the Namche... Available to Purchase

Published: 01 January 2008
Figure 6. Patterns in mean annual river power in the vicinity of the Namche Barwa–Gyala Peri massif. Areas with no data coverage were not included in the analysis. Stars denote the locations of Namche Barwa and Gyala Peri.
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Figure 5. Patterns in mean annual precipitation in the vicinity of the Namche Barwa–Gyala Peri massif. Areas with no data coverage are those with &lt;1 m of precipitation annually. Stars denote the locations of Namche Barwa and Gyala Peri.

Figure 5. Patterns in mean annual precipitation in the vicinity of the Namc... Available to Purchase

Published: 01 January 2008
Figure 5. Patterns in mean annual precipitation in the vicinity of the Namche Barwa–Gyala Peri massif. Areas with no data coverage are those with <1 m of precipitation annually. Stars denote the locations of Namche Barwa and Gyala Peri.
Book Chapter

Tectonics and topographic evolution of Namche Barwa and the easternmost Lhasa block, Tibet Available to Purchase

Author(s)
Peter K. Zeitler, Anne S. Meltzer, Lucy Brown, William S.F. Kidd, Chul Lim, Eva Enkelmann
... In the easternmost Himalaya and southeastern Tibet, the Namche Barwa–Gyala Peri massif and adjacent Lhasa block host some of the Earth’s most active geologic processes and extreme topography. Synthesis of U-Th/He and Ar-Ar thermochronology, anatectic history, seismicity, and structural geology...
Abstract
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In the easternmost Himalaya and southeastern Tibet, the Namche Barwa–Gyala Peri massif and adjacent Lhasa block host some of the Earth’s most active geologic processes and extreme topography. Synthesis of U-Th/He and Ar-Ar thermochronology, anatectic history, seismicity, and structural geology shows the important role that surface processes have played in this region in both local and orogen-scale crustal dynamics. Basement rocks of the massif underwent an episode of metamorphism, partial melting, and focused deformation that began ca. 10 Ma and likely remains active due to thermally mediated feedbacks between these processes and erosion. Strong differential rock uplift at Namche Barwa established the immense Namche Barwa knickzone on the Yarlung Tsangpo River, which has been stabilized through coupling between erosion driven by high stream power and localized deformation. This knickzone has maintained a high secondary base level of ~3000 m for the upper Yarlung Tsangpo watershed and so has shielded a large region of southeastern Tibet from excavation by the river, which in turn could alter the morphology and so the dynamics of the eastern Himalayan orogenic wedge. The landscape evolution of the southeast Lhasa block involved slow regional unroofing or incision in the Neogene, a significant pulse of ~5 km of rapid exhumation from ca. 10 to 5 Ma, and since then a great reduction in exhumation started once the Namche Barwa knickzone on the Yarlung Tsangpo was established. The low-relief high-elevation surface in the area is a relatively young feature, developed after the rapid 10–5 Ma exhumation pulse.

Journal Article

Rapid exhumation of the eastern Himalayan syntaxis since the late Miocene Available to Purchase

Karl A. Lang, Katharine W. Huntington, Russ Burmester, Bernard Housen
Journal: GSA Bulletin
Published: 01 September 2016
GSA Bulletin (2016) 128 (9-10): 1403–1422.
DOI: https://doi.org/10.1130/B31419.1
... indicate the percentages of Himalayan zircons with crystallization ages older than 300 Ma and Transhimalayan zircons younger than 300 Ma. Only Himalayan zircons are illustrated in line plots. Young cooling age components attributed to the Namche Barwa massif ( Enkelmann et al., 2011 ) persist in young lag...
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Figure 4. (A) Patterns in topographic relief in the vicinity of the Namche Barwa–Gyala Peri massif. Areas with no data coverage are those with relief &lt;2300 m. Gray stars denote the locations of sediment samples taken for 10Be analysis. Black stars show the locations of Namche Barwa and Gyala Peri. (B) 10Be basin-averaged erosion rate vs. mean topographic relief for sampled catchments.

Figure 4. (A) Patterns in topographic relief in the vicinity of the Namche ... Available to Purchase

Published: 01 January 2008
Figure 4. (A) Patterns in topographic relief in the vicinity of the Namche Barwa–Gyala Peri massif. Areas with no data coverage are those with relief <2300 m. Gray stars denote the locations of sediment samples taken for 10 Be analysis. Black stars show the locations of Namche Barwa and Gyala