Gamma radiation effects on quartz Al and Ti center electron spin resonance signal intensity; implications for quartz provenance discrimination

• Published in: The American mineralogist Vol. 107; no. 4; pp. 684 - 691
• Main Authors: Wei Chuanyi, Wei Chuanyi, Yin Gongming, Yin Gongming, Liu Chunru, Liu Chunru, Dembele, N'dji dit Jacques, Yu Lupeng, Yu Lupeng, Jiang Huajun, Jiang Huajun, Li Yawei, Li Yawei, Guo Rujun, Guo Rujun, Cheng Li, Cheng Li, Li, Wenpeng
• Format: Journal Article
• Language: English
• Published: Washington Mineralogical Society of America 01.04.2022; Walter de Gruyter GmbH
• Subjects: Al center; Aluminum; Asia; China; clastic sediments; Crystallization; Discrimination; effects; Electron paramagnetic resonance; Electron spin; Electron spin resonance; electron spin resonance (ESR); Far East; fluvial environment; Fluvial sedimentation; Fluvial sediments; framework silicates; Gamma radiation; Gamma rays; Gravel; Huai River; Huang He; ICP mass spectra; Impurities; irradiation; major elements; mass spectra; metals; Minerals; Pearl River; provenance; provenance tracing; Quartz; Radiation effects; Resonance; Rivers; sand; sed rocks, sediments; Sediment; Sedimentary petrology; Sediments; silica minerals; silicates; Songhua River; Source-to-sink system; spectra; spectroscopy; Spin resonance; stream sediments; Ti center; Titanium; Trace elements; Yangtze River; γ Radiation
• ISSN: 0003-004X; 1945-3027
• DOI: 10.2138/am-2020-7565

Quartz is one of the most common rock-forming minerals and crystallizes over a wide range of temperature and pressure conditions. This diversity of quartz crystallization environments is reflected by trace-element compositional variations, which can be used to distinguish between different source sediments. Trace elements that are incorporated into the quartz lattice form corresponding paramagnetic centers (impurity centers, such as Al and Ti centers), which can be detected using the electron spin resonance (ESR) method. However, whether the quartz impurity center ESR signal intensity (quartz ESR-SI) can be used for quartz sediment provenance tracing remains uncertain. In the present study, five present-day (modern) fluvial sediments from the Songhua, Yellow, Yangtze, Huai, and Pearl rivers in China and eight ancient fluvial sand lenses from the Yichang Gravel Layer (YGL) located in the middle Yangtze River were sampled for major- and trace-element determinations by ICP-OES and ICP-MS for the purpose of provenance discrimination. A total of 1404 ESR spectra were also collected to evaluate the effect of γ-ray dose (varying from 50 to 50 000 Gy) on quartz ESR-SI to establish the relationship between quartz element contents and quartz ESR-SIs and thereby to assess the potential utility of quartz ESR-SI for sediment provenance analysis. Results indicate that: (1) quartz collected from the different studied locations can be distinguished by element contents; (2) the quartz Al center ESR-SI increases with increasing γ-ray dose from 50 to 50 000 Gy; (3) the quartz Ti center ESR-SI increases within a γ-ray dose of 10 000 Gy and decreases beyond 10 000 Gy; (4) quartz Al and Ti center ESR-SIs are closely related to the contents of Al and Ti in quartz; and (5) a plot of quartz Ti center ESR-SI vs. Al center ESR-SI using data for a γ-ray dose range of 4000-7000 Gy is the best indicator of fluvial sediment provenance using the ESR method.