Characterization of Ambient Particulate Matter Sampled at an Active Sand Mine Facility in Northwestern Wisconsin

Volume 15, Issue 2 Pub Date : 2018-09-26 DOI:10.33697/AJUR.2018.017

Julie Zhang, Callie Fischer, J. Oster, Gabriel de Carvalho Chaves, Rachel Mooney, P. Cleary

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Abstract

Concern has arisen about levels of silica in ambient particles near sand mines in Northwestern Wisconsin. Airborne particles released from mining and processing activity may release respirable silica into the air, which can have adverse health effects on individuals exposed to significant quantities. In order to assess these levels of silica, this study developed a parallel analysis using an X-ray diffraction (XRD) and scanning electron microscopy/energy-dispersive X-ray spectroscopy (SEM-EDS) analysis to test particles in real air samples. Calibrations were constructed for the XRD analysis (following NIOSH Method 7500) with silica standards containing 10 μg – 500 μg respirable silica on filter media with detection limits of 19-28 μg. SEM-EDS methods incorporated identifying the geologic composition of particles using the elemental analysis. Real air samples were collected at a sand mining site using a cascade impactor. Filter substrates were pre-weighed and post-weighed to determine the total dry mass of particles sampled and XRD results show at maximum 16 % of the mass can be attributed to crystalline silica in the samples. An SEM-EDS analysis to categorize the particles geologic classification using ratios of elements shows more than 70% of sampled particles are classified as potassium feldspars. KEYWORDS: Particulate Matter; Sand Mining; Silica; Atmospheric Characterization; XRD; SEM-EDS; Fugitive Dust

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在威斯康辛州西北部一个活跃的沙矿设施取样的环境颗粒物质的特征

人们对威斯康辛州西北部砂矿附近环境颗粒中的二氧化硅含量感到担忧。采矿和加工活动释放的空气颗粒可能将可吸入二氧化硅释放到空气中，这可能对大量接触二氧化硅的人产生不利的健康影响。为了评估这些二氧化硅的水平，本研究开发了一种平行分析，使用x射线衍射(XRD)和扫描电子显微镜/能量色散x射线光谱(SEM-EDS)分析来测试真实空气样品中的颗粒。采用含10 ~ 500 μg可吸入二氧化硅的二氧化硅标准品，在检测限为19 ~ 28 μg的过滤介质上进行XRD分析(NIOSH Method 7500)校准。SEM-EDS方法结合了元素分析来识别颗粒的地质组成。真实的空气样本是在采砂现场使用级联冲击器收集的。对过滤底物进行了称重和后称重，以确定取样颗粒的总干质量，XRD结果表明，样品中最大16%的质量可归因于结晶二氧化硅。利用元素比例对颗粒进行地质分类的SEM-EDS分析表明，超过70%的样品颗粒被归类为钾长石。关键词:颗粒物;采砂;二氧化硅;大气特征;x射线衍射;能谱;逃亡的尘埃

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Volume 15, Issue 2

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