超高分辨率珊瑚骨骼氧同位素组成数据集（2006-2009年）

在以前的研究中，微米尺度的波岩珊瑚骨骼的氧同位素组成（δ18O）不受温度的影响。考虑到温度是宏观尺度上珊瑚δ18O的主要控制因素，需要仔细评估温度对微米尺度上珊瑚δ18O变化的影响。为了更好地了解珊瑚骨骼中高分辨率δ18O的气候和生物学意义，采用Cameca IMS 1280-HR二次离子质谱（SIMS）分析了来自南海和大堡礁的三种现代珊瑚珊瑚的原位δ18O值。SIMS分析采用了两次真空浸渍法和基于多个控制点的珊瑚基质效应校正的分段校准方法。衍生的SIMS珊瑚δ18O时间序列与月δ18O（通过常规气体同位素比值质谱测量）、月Sr/Ca和日海面温度呈一致的长期变化，首先突出了微米尺度珊瑚δ18O的主要温度控制。

In previous studies, the oxygen isotope composition (δ¹⁸O) of Pocillopora coral skeletons at the micron scale was reported to be unaffected by temperature. Given that temperature is the primary controlling factor of coral δ¹⁸O at the macroscale, the impact of temperature on micron-scale variations in coral δ¹⁸O requires careful evaluation. To better understand the climatic and biological implications of high-resolution δ¹⁸O in coral skeletons, in-situ δ¹⁸O values of three modern coral species collected from the South China Sea and the Great Barrier Reef were analyzed using a Cameca IMS 1280-HR secondary ion mass spectrometer (SIMS). The SIMS analysis employed a dual vacuum impregnation protocol and a segmented calibration strategy that corrects for coral matrix effects via multiple control points. The derived SIMS-based coral δ¹⁸O time series showed consistent long-term variations with monthly δ¹⁸O (measured via conventional gas isotope ratio mass spectrometry), monthly Sr/Ca ratios, and daily sea surface temperature (SST), which firstly highlights the dominant temperature control over micron-scale coral δ¹⁸O.