A machine learning method for distinguishing detrital zircon provenance

S. H. Zhong; Y. Liu; S. Z. Li; I. N. Bindeman; P. A. Cawood; R. Seltmann; J. H. Niu; G. H. Guo; J. Q. Liu

doi:10.1007/s00410-023-02017-9

A machine learning method for distinguishing detrital zircon provenance

S. H. Zhong, Y. Liu, S. Z. Li, I. N. Bindeman, P. A. Cawood, R. Seltmann, J. H. Niu, G. H. Guo, J. Q. Liu

School of Earth Atmosphere and Environment

Research output: Contribution to journal › Article › Research › peer-review

20 Citations (Scopus)

Abstract

Zircon geochemistry provides a sensitive monitor of its parental magma composition. However, due to the complexity of the uptake of trace elements during zircon growth, identifying source magmas remains challenging, particularly for detrital grains whose petrological context is lost. We use a machine learning-based approach to explore the classifiers for zircon provenance, based on 3794 published, high-quality zircon trace element analyses compiled from I-, S-, and A-type granites. Three supervised machine learning algorithms, namely, Support Vector Machine (SVM), Random Forest (RF), and Multilayer Perceptron (MLP) were used and trained with 11 features, including 7 trace elements (Ce, Eu, Ho, Nb, Ta, Th, and U) and 4 derived trace element ratios (Th/U, U/Yb, Ce/Ce*, and Eu/Eu*). Our results show that all three trained machine learning methods perform very well with accuracy varying from 0.86 to 0.89, and that input–output relationships captured by different ML methods are nearly consistent and can be explained by the known petrological processes. The application of our trained machine learning classifiers to detrital zircon studies will enhance the interpretability of zircon assemblages of different origins. It also helps develop interpretations, approaches, and tools that will benefit, for example, the study of continental crust evolution and mineral exploration.

Original language	English
Article number	35
Number of pages	17
Journal	Contributions of Mineralogy and Petrology
Volume	178
Issue number	6
DOIs	https://doi.org/10.1007/s00410-023-02017-9
Publication status	Published - Jun 2023

Keywords

A-type granite
Detrital zircon
I-type granite
Machine learning
Mineral exploration
S-type granite
Tectonic setting

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10.1007/s00410-023-02017-9Licence: CC BY

Cite this

@article{187af3d31d9a461bbf140b89f3080237,

title = "A machine learning method for distinguishing detrital zircon provenance",

abstract = "Zircon geochemistry provides a sensitive monitor of its parental magma composition. However, due to the complexity of the uptake of trace elements during zircon growth, identifying source magmas remains challenging, particularly for detrital grains whose petrological context is lost. We use a machine learning-based approach to explore the classifiers for zircon provenance, based on 3794 published, high-quality zircon trace element analyses compiled from I-, S-, and A-type granites. Three supervised machine learning algorithms, namely, Support Vector Machine (SVM), Random Forest (RF), and Multilayer Perceptron (MLP) were used and trained with 11 features, including 7 trace elements (Ce, Eu, Ho, Nb, Ta, Th, and U) and 4 derived trace element ratios (Th/U, U/Yb, Ce/Ce*, and Eu/Eu*). Our results show that all three trained machine learning methods perform very well with accuracy varying from 0.86 to 0.89, and that input–output relationships captured by different ML methods are nearly consistent and can be explained by the known petrological processes. The application of our trained machine learning classifiers to detrital zircon studies will enhance the interpretability of zircon assemblages of different origins. It also helps develop interpretations, approaches, and tools that will benefit, for example, the study of continental crust evolution and mineral exploration.",

keywords = "A-type granite, Detrital zircon, I-type granite, Machine learning, Mineral exploration, S-type granite, Tectonic setting",

author = "Zhong, {S. H.} and Y. Liu and Li, {S. Z.} and Bindeman, {I. N.} and Cawood, {P. A.} and R. Seltmann and Niu, {J. H.} and Guo, {G. H.} and Liu, {J. Q.}",

note = "Funding Information: We appreciate helpful reviews and constructive suggestions from Associate Editor Daniela Rubatto, Maurizio Petrelli, Coralie Siegel, and an anonymous reviewer. This work was financially supported by the Marine S&T Fund of Shandong Province for the National Laboratory for Marine Science and Technology (Qingdao) (No. 2022QNLM050302); Fundamental Research Funds for the Central Universities (202172002); the National Natural Science Foundation (42203066); and the Natural Science Foundation of Shandong Province (ZR2020QD027); Australian Research Council (FL160100168). RS acknowledges funding under Natural Environment Research Council Grant NE/P017452/1 “From arc magmas to ores (FAMOS): A mineral systems approach”. Publisher Copyright: {\textcopyright} 2023, The Author(s).",

year = "2023",

month = jun,

doi = "10.1007/s00410-023-02017-9",

language = "English",

volume = "178",

journal = "Contributions of Mineralogy and Petrology",

issn = "0010-7999",

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T1 - A machine learning method for distinguishing detrital zircon provenance

AU - Zhong, S. H.

AU - Liu, Y.

AU - Li, S. Z.

AU - Bindeman, I. N.

AU - Cawood, P. A.

AU - Seltmann, R.

AU - Niu, J. H.

AU - Guo, G. H.

AU - Liu, J. Q.

N1 - Funding Information: We appreciate helpful reviews and constructive suggestions from Associate Editor Daniela Rubatto, Maurizio Petrelli, Coralie Siegel, and an anonymous reviewer. This work was financially supported by the Marine S&T Fund of Shandong Province for the National Laboratory for Marine Science and Technology (Qingdao) (No. 2022QNLM050302); Fundamental Research Funds for the Central Universities (202172002); the National Natural Science Foundation (42203066); and the Natural Science Foundation of Shandong Province (ZR2020QD027); Australian Research Council (FL160100168). RS acknowledges funding under Natural Environment Research Council Grant NE/P017452/1 “From arc magmas to ores (FAMOS): A mineral systems approach”. Publisher Copyright: © 2023, The Author(s).

PY - 2023/6

Y1 - 2023/6

N2 - Zircon geochemistry provides a sensitive monitor of its parental magma composition. However, due to the complexity of the uptake of trace elements during zircon growth, identifying source magmas remains challenging, particularly for detrital grains whose petrological context is lost. We use a machine learning-based approach to explore the classifiers for zircon provenance, based on 3794 published, high-quality zircon trace element analyses compiled from I-, S-, and A-type granites. Three supervised machine learning algorithms, namely, Support Vector Machine (SVM), Random Forest (RF), and Multilayer Perceptron (MLP) were used and trained with 11 features, including 7 trace elements (Ce, Eu, Ho, Nb, Ta, Th, and U) and 4 derived trace element ratios (Th/U, U/Yb, Ce/Ce*, and Eu/Eu*). Our results show that all three trained machine learning methods perform very well with accuracy varying from 0.86 to 0.89, and that input–output relationships captured by different ML methods are nearly consistent and can be explained by the known petrological processes. The application of our trained machine learning classifiers to detrital zircon studies will enhance the interpretability of zircon assemblages of different origins. It also helps develop interpretations, approaches, and tools that will benefit, for example, the study of continental crust evolution and mineral exploration.

AB - Zircon geochemistry provides a sensitive monitor of its parental magma composition. However, due to the complexity of the uptake of trace elements during zircon growth, identifying source magmas remains challenging, particularly for detrital grains whose petrological context is lost. We use a machine learning-based approach to explore the classifiers for zircon provenance, based on 3794 published, high-quality zircon trace element analyses compiled from I-, S-, and A-type granites. Three supervised machine learning algorithms, namely, Support Vector Machine (SVM), Random Forest (RF), and Multilayer Perceptron (MLP) were used and trained with 11 features, including 7 trace elements (Ce, Eu, Ho, Nb, Ta, Th, and U) and 4 derived trace element ratios (Th/U, U/Yb, Ce/Ce*, and Eu/Eu*). Our results show that all three trained machine learning methods perform very well with accuracy varying from 0.86 to 0.89, and that input–output relationships captured by different ML methods are nearly consistent and can be explained by the known petrological processes. The application of our trained machine learning classifiers to detrital zircon studies will enhance the interpretability of zircon assemblages of different origins. It also helps develop interpretations, approaches, and tools that will benefit, for example, the study of continental crust evolution and mineral exploration.

KW - A-type granite

KW - Detrital zircon

KW - I-type granite

KW - Machine learning

KW - Mineral exploration

KW - S-type granite

KW - Tectonic setting

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U2 - 10.1007/s00410-023-02017-9

DO - 10.1007/s00410-023-02017-9

M3 - Article

AN - SCOPUS:85160055051

SN - 0010-7999

VL - 178

JO - Contributions of Mineralogy and Petrology

JF - Contributions of Mineralogy and Petrology

IS - 6

M1 - 35

ER -

A machine learning method for distinguishing detrital zircon provenance

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A machine learning method for distinguishing detrital zircon provenance

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