Clay mineral-based sustainable snow contaminant remediation technology†

Benilde Mizero, Saba Naderi, Sandeep Bose, Houjie Li and Parisa A. Ariya
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Abstract

Seasonal snow covers up to 33% of the Earth's surface. Fresh falling snow serves as a snapshot of atmospheric processes and can take up pollutants. Once deposited, snow can affect the Earth's radiation and climate change, and its melting and accumulation processes can affect human health. Little has been done for snow pollution remediation, especially regarding emerging materials and nano/microplastics in urban regions. We present a sustainable, cost-effective snow remediation filtering system made of multilayer clay-based minerals, specifically kaolin and montmorillonite, capable of removing nano/micro-contaminants from snow. In addition, a recycled metallic mesh with various pore sizes, including nano/micro size, can remove substantial snow contaminants. Using a suite of technologies including high-resolution S/TEM, Pelletier ice nucleation counter, NALDI mass spectrometry, Photoacoustic Extinctiometer (PAX), triple quad ICP-MS/MS, and TOC counter, we found that the clay-mineral setup is highly efficient. For instance, it removes metallic species (>95%), plastic micro/nanoparticles like polyethylene glycol and polyethylene (>99%), black carbon (>93%), and total organic carbon (>50%) from dirty snow sampled in the primary snow depository in downtown Montreal. This sustainable and inexpensive method is promising for significantly reducing the environmental impact of snow pollutants, improving current snow remediation practices in urban areas, decreasing the re-emission of contaminants in air, soil, and water leaching, and improving the ecosystem and human health.

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基于粘土矿物的可持续雪地污染物修复技术†。
季节性降雪覆盖了地球表面的 33%。新降雪是大气过程的缩影,并能吸收污染物。雪一旦沉积下来,就会影响地球辐射和气候变化,其融化和积聚过程也会影响人类健康。在雪污染修复方面,特别是在城市地区的新兴材料和纳米/微塑料方面,我们所做的工作还很少。我们提出了一种可持续的、具有成本效益的雪净化过滤系统,该系统由多层粘土矿物(特别是高岭土和蒙脱石)制成,能够去除雪中的纳米/微污染物。此外,具有不同孔径(包括纳米/微米)的回收金属网也能去除大量雪污染物。利用高分辨率 S/TEM、Pelletier 冰成核计数器、NALDI 质谱仪、光声灭绝仪 (PAX)、三重 ICP-MS/MS 和 TOC 计数器等一系列技术,我们发现粘土矿物装置非常高效。例如,它可以去除蒙特利尔市中心主要积雪沉积区采样的脏雪中的金属物质(95%)、塑料微粒/纳米微粒(如聚乙二醇和聚乙烯)(99%)、黑碳(93%)和总有机碳(50%)。这种可持续且成本低廉的方法有望显著减少雪污染物对环境的影响,改善城市地区目前的雪修复方法,减少污染物在空气、土壤和水浸泡中的再次排放,改善生态系统和人类健康。
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