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Optically sizing single atmospheric particulates with a 10-nm resolution using a strong evanescent field.


ABSTRACT: Although an accurate evaluation of the distribution of ultrafine particulate matter in air is of utmost significance to public health, the usually used PM2.5 index fails to provide size distribution information. Here we demonstrate a low-profile and cavity-free size spectrometer for probing fine and ultrafine particulate matter by using the enhanced particle-perturbed scattering in strong optical evanescent fields of a nanofiber array. The unprecedented size resolution reaches 10?nm for detecting single 100-nm-diameter nanoparticles by employing uniform nanofibers and controlling the polarizations of the probe light. This size spectrometry was tested and used to retrieve the size distribution of particulate matter in the air of Beijing, yielding mass concentrations of nanoparticles, as a secondary exercise, consistent with the officially released data. This nanofiber-array probe shows potential for the full monitoring of air pollution and for studying early-stage haze evolution and can be further extended to explore nanoparticle interactions.

SUBMITTER: Yu XC 

PROVIDER: S-EPMC6060056 | biostudies-literature | 2018

REPOSITORIES: biostudies-literature

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Optically sizing single atmospheric particulates with a 10-nm resolution using a strong evanescent field.

Yu Xiao-Chong XC   Zhi Yanyan Y   Tang Shui-Jing SJ   Li Bei-Bei BB   Gong Qihuang Q   Qiu Cheng-Wei CW   Xiao Yun-Feng YF  

Light, science & applications 20180420


Although an accurate evaluation of the distribution of ultrafine particulate matter in air is of utmost significance to public health, the usually used PM<sub>2.5</sub> index fails to provide size distribution information. Here we demonstrate a low-profile and cavity-free size spectrometer for probing fine and ultrafine particulate matter by using the enhanced particle-perturbed scattering in strong optical evanescent fields of a nanofiber array. The unprecedented size resolution reaches 10 nm f  ...[more]

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