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Metadata Files

Data Publication

GEOSCRAPE zircon database

Martin, Erin L. | Barrote, Vitor R. | Cawood, Peter A.

GFZ Data Services

(2024)

This database contains a compilation of published zircon geochronology, chemistry and isotope data. The database was created through automated web scraping of the Figshare data repository. Data included U-Pb and Pb-Pb dating, Lu-Hf isotopes, trace element and rare earth element chemistry and isotopes. Where available, metadata on the analytical method, lithology, sample description and sampling coordinates are included. All analyses include a citation and doi link to the original data hosted on Figshare. See metadata table for descriptions of table headers. See associated manuscript for web scraping code.

Keywords


Originally assigned keywords
data compilation
zircon geochronology
geochemistry data
isotope data
GEOROC Expert Dataset
zircon
magmatic
detrital
UPb age
PbPb age
LuHf isotopes
trace elements
rare earth elements
adakite
amphibolite
andesite
anorthosite
aplite
arenite
ash
basalt
basaltic andesite
basaltic trachyandesite
bentonite
biotitite
charnockite
conglomerate
dacite
diamictite
diorite
dolerite
dunite
gabbro
granite
granodiorite
granulite
greenschist
greywacke
hornblendite
kersantite
kimberlite
lamprophyre
leucogranite
lherzolite
limestone
migmatite
monzodiorite
monzogranite
monzonite
norite
orthogneiss
paragneiss
pegmatite
pelite
psammite
pumice
pyroxenite
quartzite
radiolarite
rhyodacite
rhyolite
rodingite
sandstone
schist
serpentinite
shale
siltstone
spessartite
syenite
syenogranite
tonalite
trachyandesite
trachydacite
trachyte
trondhjemite
tuff
GEOCHEMISTRY
GEOCHEMICAL PROPERTIES
ISOTOPE MEASUREMENTS
ISOTOPE RATIOS
ISOTOPES
ISOTOPIC AGE
MINERAL AGE DETERMINATIONS

Corresponding MSL vocabulary keywords
zircon
uranium-lead dating
uranium-lead age
lead-lead dating
lead-lead age
trace elements
trace elements
amphibolite
andesite
anorthosite
aplite
arenite
basalt
bentonite
conglomerate
dacite
diorite
dolerite
gabbro
granite
granodiorite
granulite
greenschist
hornblendite
limestone
migmatite
monzonite
pegmatite
mudstone
pumice
pumice
pumice
pyroxenite
quartzite
rhyolite
rodingite
sandstone
schist
serpentinite
shale
siltstone
syenite
tonalite
trachyte
tuff

MSL enriched keywords
minerals
silicate minerals
nesosilicates
zircon
analysis
geochronology
uranium dating
uranium-lead dating
measured property
age of sample
uranium age
uranium-lead age
lead-lead dating
lead-lead age
microchemical analysis
trace elements
whole rock analysis
trace elements
metamorphic rock
amphibolite
igneous rock - extrusive
intermediate extrusive
andesite
igneous rock - intrusive
intermediate intrusive
anorthosite
acidic intrusive
aplite
sedimentary rock
sandstone
arenite
basic extrusive
basalt
phyllosilicates
clay - smectite
bentonite
conglomerate
acidic extrusive
dacite
diorite
basic intrusive
dolerite
gabbro
granite
granodiorite
granulite
schist
greenschist
ultrabasic intrusive
hornblendite
limestone
migmatite
monzonite
pegmatite
mudstone
volcanic glass
pumice
unconsolidated sediment
tephra
pumice
analogue modelling material
granular modelling material
natural granular material
pumice
pyroxenite
quartzite
rhyolite
metasomatic rock
rodingite
serpentinite
shale
siltstone
syenite
tonalite
trachyte
pyroclastic rock
tuff
lutetium-hafnium dating
lutetium-hafnium age

MSL enriched sub domains i

geochemistry

Source

http://dx.doi.org/10.5880/digis.e.2024.003

Source publisher

GFZ Data Services


DOI

10.5880/digis.e.2024.003


Authors

Martin, Erin L.

0000-0002-6426-3729

Monash University, Clayton, Victoria, Australia;

Barrote, Vitor R.

0000-0001-7442-9748

Monash University, Clayton, Victoria, Australia;

Cawood, Peter A.

0000-0003-1200-3826

Monash University, Clayton, Victoria, Australia;


Contributers

Martin, Erin L.

ContactPerson

Monash University, Clayton, Victoria, Australia;

Martin, Erin L.

ContactPerson

Monash University, Clayton, Victoria, Australia;

DIGIS Team

ContactPerson

Göttingen University, Göttingen, Germany;


References

Martin, E. L. (2022). <i>GEOSCRAPE zircon database</i> [Data set]. GRO.data. https://doi.org/10.25625/FWQ7DT

10.25625/FWQ7DT

IsIdenticalTo

Martin, E. L., Barrote, V. R., & Cawood, P. A. (2022). A resource for automated search and collation of geochemical datasets from journal supplements. Scientific Data, 9(1). https://doi.org/10.1038/s41597-022-01730-7

10.1038/s41597-022-01730-7

IsSupplementTo

References

References

Abdul Shakoor, M., Yang, X., Deng, J., & Hakro, A. A. A. D. (2018). Early Neoproterozoic evolution of Southeast Pakistan: evidence from geochemistry, geochronology, and isotopic composition of the Nagarparkar Igneous Complex. International Geology Review, 61(11), 1391–1408. https://doi.org/10.1080/00206814.2018.1512905

10.1080/00206814.2018.1512905

Cites

Andersen, T., Andersson, U. B., Graham, S., Åberg, G., & Simonsen, S. L. (2009). Granitic magmatism by melting of juvenile continental crust: new constraints on the source of Palaeoproterozoic granitoids in Fennoscandia from Hf isotopes in zircon. Journal of the Geological Society, 166(2), 233–247. https://doi.org/10.1144/0016-76492007-166

10.1144/0016-76492007-166

Cites

Andersen, T., Elburg, M., & Cawthorn-Blazeby, A. (2015). U–Pb and Lu–Hf zircon data in young sediments reflect sedimentary recycling in eastern South Africa. Journal of the Geological Society, 173(2), 337–351. https://doi.org/10.1144/jgs2015-006

10.1144/jgs2015-006

Cites

Andresen, A., Agyei-Dwarko, N. Y., Kristoffersen, M., & Hanken, N.-M. (2014). A Timanian foreland basin setting for the late Neoproterozoic–Early Palaeozoic cover sequences (Dividal Group) of northeastern Baltica. Geological Society, London, Special Publications, 390(1), 157–175. https://doi.org/10.1144/sp390.29

10.1144/SP390.29

Cites

Archibald, D. B., Macquarrie, L. M. G., Murphy, J. B., Strachan, R. A., McFarlane, C. R. M., Button, M., Larson, K. P., & Dunlop, J. (2021). The construction of the Donegal composite batholith, Irish Caledonides: Temporal constraints from U-Pb dating of zircon and titanite. GSA Bulletin. https://doi.org/10.1130/b35856.1

10.1130/B35856.1

Cites

Attia, S., Paterson, S. R., Saleeby, J., & Cao, W. (2021). Detrital zircon provenance and depositional links of Mesozoic Sierra Nevada intra-arc strata. Geosphere, 17(5), 1422–1453. https://doi.org/10.1130/ges02296.1

10.1130/GES02296.1

Cites

AUGUSTSSON, C., MÜNKER, C., BAHLBURG, H., & FANNING, C. M. (2006). Provenance of late Palaeozoic metasediments of the SW South American Gondwana margin: a combined U–Pb and Hf-isotope study of single detrital zircons. Journal of the Geological Society, 163(6), 983–995. https://doi.org/10.1144/0016-76492005-149

10.1144/0016-76492005-149

Cites

Be’eri-Shlevin, Y., Avigad, D., Gerdes, A., & Zlatkin, O. (2013). Detrital zircon U–Pb–Hf systematics of Israeli coastal sands: new perspectives on the provenance of Nile sediments. Journal of the Geological Society, 171(1), 107–116. https://doi.org/10.1144/jgs2012-151

10.1144/jgs2012-151

Cites

Beranek, L. P., van Staal, C. R., McClelland, W. C., Israel, S., & Mihalynuk, M. G. (2013). Baltican crustal provenance for Cambrian–Ordovician sandstones of the Alexander terrane, North American Cordillera: evidence from detrital zircon U–Pb geochronology and Hf isotope geochemistry. Journal of the Geological Society, 170(1), 7–18. https://doi.org/10.1144/jgs2012-028

10.1144/jgs2012-028

Cites

Boekhout, F., Roberts, N. M. W., Gerdes, A., & Schaltegger, U. (2013). A Hf-isotope perspective on continent formation in the south Peruvian Andes. Geological Society, London, Special Publications, 389(1), 305–321. https://doi.org/10.1144/sp389.6

10.1144/SP389.6

Cites

Brennan, D. T., Li, Z.-X., Rankenburg, K., Evans, N., Link, P. K., Nordsvan, A. R., Kirkland, C. L., Mahoney, J. B., Johnson, T., & McDonald, B. J. (2021). Recalibrating Rodinian rifting in the northwestern United States. Geology, 49(6), 617–622. https://doi.org/10.1130/g48435.1

10.1130/G48435.1

Cites

Bruno, H., Heilbron, M., Strachan, R., Fowler, M., de Morisson Valeriano, C., Bersan, S., Moreira, H., Cutts, K., Dunlop, J., Almeida, R., Almeida, J., & Storey, C. (2021). Earth’s new tectonic regime at the dawn of the Paleoproterozoic: Hf isotope evidence for efficient crustal growth and reworking in the São Francisco craton, Brazil. Geology, 49(10), 1214–1219. https://doi.org/10.1130/g49024.1

10.1130/G49024.1

Cites

Busby, C., Graettinger, A., Martínez, M. L., Medynski, S., Niemi, T., Andrews, C., Bowman, E., Gutierrez, E. P., Henry, M., Lodes, E., Ojeda, J., Rice, J., Andrews, G., & Brown, S. (2020). Volcanic record of the arc-to-rift transition onshore of the Guaymas basin in the Santa Rosalía area, Gulf of California, Baja California. Geosphere, 16(4), 1012–1041. https://doi.org/10.1130/ges02094.1

10.1130/GES02094.1

Cites

Cao, G.-Y., Xue, H.-M., Liu, Z., & Lu, Z.-L. (2018). U–Pb zircon, geochemical, and Sr–Nd–Hf isotopic data for late Mesozoic volcanic rocks along the Tan–Lu fault zone of Shandong Province, eastern China: constraints on magma genesis and lithospheric thinning. International Geology Review, 61(8), 972–996. https://doi.org/10.1080/00206814.2018.1487340

10.1080/00206814.2018.1487340

Cites

Cao, H.-W., Zhang, Y.-H., Tang, L., Hollis, S. P., Zhang, S.-T., Pei, Q.-M., Yang, C., & Zhu, X.-S. (2018). Geochemistry, zircon U–Pb geochronology and Hf isotopes of Jurassic-Cretaceous granites in the Tengchong terrane, SW China: implications for the Mesozoic tectono-magmatic evolution of the Eastern Tethyan Tectonic Domain. International Geology Review, 61(3), 257–279. https://doi.org/10.1080/00206814.2017.1422445

10.1080/00206814.2017.1422445

Cites


Contact

DIGIS Team

Göttingen University, Göttingen, Germany;

DIGIS Team

Göttingen University, Göttingen, Germany;

DIGIS Team

Göttingen University, Göttingen, Germany;


Citiation

Martin, E. L., Barrote, V. R., & Cawood, P. A. (2024). GEOSCRAPE zircon database [Data set]. GFZ Data Services. https://doi.org/10.5880/DIGIS.E.2024.003