Yunyan Ni scite author profile

An interlaboratory study of Mg/Ca and Sr/Ca ratios in three commercially available carbonate reference materials (BAM RS3, CMSI 1767, and ECRM 752‐1) was performed with the participation of 25 laboratories that determine foraminiferal Mg/Ca ratios worldwide. These reference materials containing Mg/Ca in the range of foraminiferal calcite (0.8 mmol/mol to 6 mmol/mol) were circulated with a dissolution protocol for analysis. Participants were asked to make replicate dissolutions of the powdered samples and to analyze them using the instruments and calibration standards routinely used in their laboratories. Statistical analysis was performed in accordance with the International Standardization Organization standard 5725, which is based on the analysis of variance (ANOVA) technique. Repeatability (RSDr%), an indicator of intralaboratory precision, for Mg/Ca determinations in solutions after centrifuging increased with decreasing Mg/Ca, ranging from 0.78% at Mg/Ca = 5.56 mmol/mol to 1.15% at Mg/Ca = 0.79 mmol/mol. Reproducibility (RSDR%), an indicator of the interlaboratory method precision, for Mg/Ca determinations in centrifuged solutions was noticeably worse than repeatability, ranging from 4.5% at Mg/Ca = 5.56 mmol/mol to 8.7% at Mg/Ca = 0.79 mmol/mol. Results of this study show that interlaboratory variability is dominated by inconsistencies among instrument calibrations and highlight the need to improve interlaboratory compatibility. Additionally, the study confirmed the suitability of these solid standards as reference materials for foraminiferal Mg/Ca (and Sr/Ca) determinations, provided that appropriate procedures are adopted to minimize and to monitor possible contamination from silicate mineral phases.

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A core top assessment of proxies for the ocean carbonate system in surface‐dwelling foraminifers

Ni¹,

et al. 2007

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[1] We have assessed the reliability of several foraminifer-hosted proxies of the ocean carbonate system (d 11 B, B/Ca, and U/Ca) using Holocene samples from the Atlantic and Pacific oceans. We examined chemical variability over a range of test sizes for two surface-dwelling foraminifers (Globigerinoides sacculifer and Globigerinoides ruber). Measurements of d 11 B in G. ruber show no significant relationship with test size in either Atlantic or Pacific sites and appear to provide a robust proxy of surface seawater pH. Likewise there is no significant variability in the d 11 B of our Atlantic core top G. sacculifer, but we find that d 11 B increases with increasing test size for G. sacculifer in the Pacific. These systematic differences in d 11 B are inferred to be a consequence of isotopically light gametogenic calcite in G. sacculifer and its preferential preservation during postdepositional dissolution. The trace element ratio proxies of ocean carbonate equilibria, U/Ca and B/Ca, show systematic increases in both G. ruber and G. sacculifer with increasing test size, possibly as a result of changing growth rates. This behavior complicates their use in paleoceanographic reconstructions. In keeping with several previous studies we find that Mg/Ca ratios increase with increasing size fraction in our wellpreserved Atlantic G. sacculifer but not in G. ruber. In contrast to previous interpretations we suggest that these observations reflect a proportionally larger influence of compositionally distinct gametogenic calcite in small individuals compared to larger ones. As with d 11 B this influences G. sacculifer but not G. ruber, which has negligible gametogenic calcite.

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Significances of studies on natural gas geology and geochemistry for natural gas industry in China

Dai

Zhou

et al. 2008

Petroleum Exploration and Development

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Tight gas in China and its significance in exploration and exploitation

Dai

2012

Petroleum Exploration and Development

252

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Accurate and precise isotopic measurement of sub-nanogram sized samples of foraminiferal hosted boron by total evaporation NTIMS

Foster

Haley

et al. 2006

Chemical Geology

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Geochemical characteristics of marine and terrestrial shale gas in China

Dai

Zou

Dong

et al. 2016

Marine and Petroleum Geology

158

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Stable carbon and hydrogen isotopes of natural gases sourced from the Xujiahe Formation in the Sichuan Basin, China

Dai

Zou

2012

Organic Geochemistry

109

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Yunyan Ni

Geochemistry of the extremely high thermal maturity Longmaxi shale gas, southern Sichuan Basin

Interlaboratory comparison study of calibration standards for foraminiferal Mg/Ca thermometry

A core top assessment of proxies for the ocean carbonate system in surface‐dwelling foraminifers

Significances of studies on natural gas geology and geochemistry for natural gas industry in China

Tight gas in China and its significance in exploration and exploitation

Accurate and precise isotopic measurement of sub-nanogram sized samples of foraminiferal hosted boron by total evaporation NTIMS

Geochemical characteristics of marine and terrestrial shale gas in China

Stable carbon and hydrogen isotopes of natural gases sourced from the Xujiahe Formation in the Sichuan Basin, China

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