量化生物碳酸盐生成的新型多尺度μCT表征方法

IF 8.5 1区 地球科学 Q1 GEOSCIENCES, MULTIDISCIPLINARY
V. Chandra , R. Sicat , F. Benzoni , V. Vahrenkamp , V. Bracchi
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引用次数: 0

摘要

有孔虫-藻类结核等生物碳酸盐结构是海洋碳酸盐生成的重要组成部分,越来越多地被用作全球碳循环预测建模和海洋酸化研究的古环境指标。然而,表征和量化生物结核碳酸盐生成的传统方法通常仅限于使用光学和电子显微镜进行二维分析。虽然微型计算机断层扫描(µCT)是对地质材料内部结构进行三维分析的绝佳工具,但样本大小与图像分辨率之间的权衡往往是一个限制因素。在本研究中,我们采用一种新颖的多尺度µCT图像分析方法,结合电子显微镜,对生物成因钙质结核中的碳酸盐体积进行可视化和量化,从而解决了这些难题。我们将这一方法应用于从沙特阿拉伯 NEOM 海岸红海采集的有孔虫-藻类结核。µCT和扫描电镜图像综合分析显示,该结核的主要生物碳酸盐成分是包壳有孔虫(EF)和壳层珊瑚藻(CCA)。我们为这项研究开发了一种多尺度 µCT 分析方法,包括基于阈值和机器学习的混合图像分割。我们利用样本的高分辨率 µCT 扫描作为基础数据,改进了低分辨率全容积 µCT 扫描的分割,为 EF 和 CCA 层提供了可靠的容积量化。EF 层和 CCA 层合计约占所研究 FAN 体积的 65.5%,分别相当于 69.01 立方厘米和 73.32 立方厘米,其余部分由沉积物填充、空隙和其他次要成分组成。此外,体积量化结果与 CT 密度值相结合表明,有孔虫-藻类结核中碳酸盐生成量最高的是 CCA 层。本研究开发的方法适用于分析生物碳酸盐结构,应用范围广泛,包括量化碳酸盐产量和研究海洋酸化对海洋钙化生物骨骼结构的影响。特别是,我们在本研究中采用的混合 µCT 图像分析方法被证明是分析生物成因结构的有利方法,在这种结构中,尽管 CT 密度值范围有重叠,但内部各层的纹理和成分却清晰可见。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

A novel multi-scale μCT characterization method to quantify biogenic carbonate production

A novel multi-scale μCT characterization method to quantify biogenic carbonate production

Biogenic carbonate structures such as rhodoliths and foraminiferal-algal nodules are a significant part of marine carbonate production and are being increasingly used as paleoenvironmental indicators for predictive modeling of the global carbon cycle and ocean acidification research. However, traditional methods to characterize and quantify the carbonate production of biogenic nodules are typically limited to two-dimensional analysis using optical and electron microscopy. While micro-computed tomography (µCT) is an excellent tool for 3D analysis of inner structures of geomaterials, the trade-off between sample size and image resolution is often a limiting factor. In this study, we address these challenges by using a novel multi-scale µCT image analysis methodology combined with electron microscopy, to visualize and quantify the carbonate volumes in a biogenic calcareous nodule. We applied our methodology to a foraminiferal-algal nodule collected from the Red Sea along the coast of NEOM, Saudi Arabia. Integrated µCT and SEM image analyses revealed the main biogenic carbonate components of this nodule to be encrusting foraminifera (EF) and crustose coralline algae (CCA). We developed a multi-scale µCT analysis approach for this study, involving a hybrid thresholding and machine-learning based image segmentation. We utilized a high resolution µCT scan from the sample as a ground-truth to improve the segmentation of the lower resolution full volume µCT scan which provided reliable volumetric quantification of the EF and CCA layers. Together, the EF and CCA layers contribute to approximately 65.5 % of the studied FAN volume, corresponding to 69.01 cm3 and 73.32 cm3 respectively, and the rest is comprised of sediment infill, voids and other minor components. Moreover, volumetric quantification results in conjunction with CT density values, indicate that the CCA layers are associated with the highest amount of carbonate production within this foraminiferal-algal nodule. The methodology developed for this study is suitable for analyzing biogenic carbonate structures for a wide array of applications including quantification of carbonate production and studying the impact of ocean acidification on skeletal structures of marine calcifying organisms. In particular, the hybrid µCT image analysis we adopted in this study proved to be advantageous for the analysis of biogenic structures in which the textures and components of the internal layers are distinctly visible despite having an overlap in the range of CT density values.

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来源期刊
Geoscience frontiers
Geoscience frontiers Earth and Planetary Sciences-General Earth and Planetary Sciences
CiteScore
17.80
自引率
3.40%
发文量
147
审稿时长
35 days
期刊介绍: Geoscience Frontiers (GSF) is the Journal of China University of Geosciences (Beijing) and Peking University. It publishes peer-reviewed research articles and reviews in interdisciplinary fields of Earth and Planetary Sciences. GSF covers various research areas including petrology and geochemistry, lithospheric architecture and mantle dynamics, global tectonics, economic geology and fuel exploration, geophysics, stratigraphy and paleontology, environmental and engineering geology, astrogeology, and the nexus of resources-energy-emissions-climate under Sustainable Development Goals. The journal aims to bridge innovative, provocative, and challenging concepts and models in these fields, providing insights on correlations and evolution.
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