白云石
菱镁矿
方解石
化学
碳酸盐
矿物学
粒度
磷酸
碳酸盐矿物
稳定同位素比值
分析化学(期刊)
地质学
色谱法
镁
有机化学
物理
地貌学
量子力学
作者
Soujung Kim,Sang‐Tae Kim,Martin Knyf
摘要
ABSTRACT Rationale Carbonate minerals are one of the most popular samples for an automated sample preparation system for CF‐IRMS, such as GasBench II and iso FLOW, but no standardized analytical protocols exist. This study gives guidelines on optimal analytic conditions for carbon and oxygen isotope analysis of Ca–Mg carbonates when using the carbonate–phosphoric acid reaction method. Methods Calcite (CaCO 3 –McMaster Carrara), dolomite (CaMg(CO 3 ) 2 –MRSI Dolomite), and magnesite (MgCO 3 –ROM Brazil Magnesite) with two grain size fractions (< 74 and 149–250 μm) were reacted with 103% (specific gravity of 1.92) phosphoric acid under He atmosphere in 12‐mL borosilicate glass vials to examine the full δ 13 C and δ 18 O evolution of acid‐liberated CO 2 for an extended reaction time of up to 12–30 days at 25°C and up to 3–7 days at 72°C. Results At 25°C, the optimal reaction time of calcite is 1 day for both grain size fractions while the optimal reaction time of 2–10 day is suggested for dolomite with a grain size of < 74 μm. At 72°C, 30‐min to 12‐h or 45‐min to 12‐h reaction is optimal for calcite with < 74‐μm or 149‐ to 250‐μm grain size fraction, respectively, whereas dolomite requires 12‐h to 1‐day reaction for both grain size fractions. The only optimal condition for magnesite is 6–7 days of reaction with < 74‐μm grain size at 72°C. Conclusions To determine precise and accurate δ 13 C and δ 18 O values of a carbonate mineral using the carbonate–phosphoric acid reaction method, an optimal reaction time must be assessed for a given analytical condition to avoid nonequilibrium isotope effects and unnecessary oxygen isotope exchange of acid‐liberated CO 2 in the carbonate reaction vessel. Our experimental result provides a guideline for the accurate and precise stable isotope analysis of Ca–Mg carbonate minerals.
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