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Detection Methods
Nanoplastics
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Super-resolution Raman imaging towards visualisation of nanoplastics
Analytical Methods2023
16 citations
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Citation count from OpenAlex, updated daily. May differ slightly from the publisher's own count.
Score: 45
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0–100 AI score estimating relevance to the microplastics field. Papers below 30 are filtered from public browse.
Yunlong Luo,
Cheng Fang,
Cheng Fang,
Cheng Fang,
Cheng Fang,
Cheng Fang,
Yunlong Luo,
Yunlong Luo,
Yunlong Luo,
Yunlong Luo,
Yunlong Luo,
Yunlong Luo,
Yunlong Luo,
Yunlong Luo,
Yunlong Luo,
Cheng Fang,
Yunlong Luo,
Yunlong Luo,
Yunlong Luo,
Yunlong Luo,
Yunlong Luo,
Cheng Fang,
Cheng Fang,
Cheng Fang,
Cheng Fang,
Cheng Fang,
Cheng Fang,
Cheng Fang,
Cheng Fang,
Cheng Fang,
Cheng Fang,
Cheng Fang,
Cheng Fang,
Cheng Fang,
Cheng Fang,
Cheng Fang,
Cheng Fang,
Cheng Fang,
Yunlong Luo,
Yunlong Luo,
Yunlong Luo,
Yunlong Luo,
Yunlong Luo,
Yunlong Luo,
Ravi Naidu
Yunlong Luo,
Yunlong Luo,
Ravi Naidu
Yunlong Luo,
Yunlong Luo,
Yunlong Luo,
Yunlong Luo,
Ravi Naidu
Ravi Naidu
Yunlong Luo,
Yunlong Luo,
Yunlong Luo,
Yunlong Luo,
Cheng Fang,
Ravi Naidu
Ravi Naidu
Ravi Naidu
Ravi Naidu
Cheng Fang,
Ravi Naidu
Yunlong Luo,
Cheng Fang,
Ravi Naidu
Ravi Naidu
Ravi Naidu
Ravi Naidu
Ravi Naidu
Ravi Naidu
Ravi Naidu
Ravi Naidu
Ravi Naidu
Ravi Naidu
Cheng Fang,
Cheng Fang,
Cheng Fang,
Cheng Fang,
Cheng Fang,
Cheng Fang,
Yunlong Luo,
Yunlong Luo,
Ravi Naidu,
Ravi Naidu
Ravi Naidu
Ravi Naidu
Cheng Fang,
Ravi Naidu
Ravi Naidu
Ravi Naidu
Cheng Fang,
Cheng Fang,
Ravi Naidu
Cheng Fang,
Ravi Naidu
Cheng Fang,
Ravi Naidu
Cheng Fang,
Ravi Naidu
Ravi Naidu
Ravi Naidu
Ravi Naidu
Ravi Naidu
Cheng Fang,
Cheng Fang,
Ravi Naidu
Ravi Naidu
Cheng Fang,
Ravi Naidu
Cheng Fang,
Ravi Naidu
Cheng Fang,
Cheng Fang,
Cheng Fang,
Cheng Fang,
Cheng Fang,
Cheng Fang,
Cheng Fang,
Cheng Fang,
Cheng Fang,
Ravi Naidu
Ravi Naidu
Ravi Naidu
Ravi Naidu
Ravi Naidu
Ravi Naidu
Ravi Naidu
Ravi Naidu
Ravi Naidu
Ravi Naidu
Cheng Fang,
Cheng Fang,
Ravi Naidu
Cheng Fang,
Ravi Naidu
Yunlong Luo,
Cheng Fang,
Cheng Fang,
Cheng Fang,
Yunlong Luo,
Ravi Naidu
Cheng Fang,
Ravi Naidu
Cheng Fang,
Ravi Naidu
Cheng Fang,
Ravi Naidu
Ravi Naidu
Summary
Super-resolution Raman imaging was evaluated as a method to visualize nanoplastics smaller than the conventional diffraction-limited laser spot size, overcoming a key barrier in nanoplastic characterization. The technique extends confocal Raman capabilities into the nanoscale detection range needed for environmental nanoplastic analysis.
Confocal Raman imaging can potentially identify and visualise microplastics and nanoplastics, but the imaging lateral resolution is hampered by the diffraction of the laser, making it difficult to analyse nanoplastics that are smaller than the laser spot and the lateral resolution limit (<i>λ</i>/2NA). Fortunately, once a nanoplastic is scanned to collect the spectrum <i>via</i> a position/pixel array as a spectrum matrix, akin to a hyperspectral matrix, the nanoplastic can be imaged by mapping the spectrum intensity as a pattern that is transcended axially and can be fitted as a 2D Gaussian surface. The Gaussian fitting and image re-construction by deconvolution can precisely predict the nanoplastic's position and approximate size, and potentially enhance the signal intensity. Several algorithms are also employed to decode the spectrum matrix, to improve the Raman images before the subsequent image re-construction. Overall, general confocal microscopy can also break through the diffraction limit of the excitation light by using algorithms, resulting in super-resolution Raman imaging to capture nanoplastics.