近临界CO₂中光热信号的千倍增强

Thousand-Fold Enhancement of Photothermal Signals in Near-Critical CO.

作者信息

Wang Yonghui, Adhikari Subhasis, van der Meer Harmen, Liu Junyan, Orrit Michel

机构信息

Huygens-Kamerlingh Onnes Laboratory, Leiden University; 2300 RA Leiden, The Netherlands.

School of Mechatronics Engineering, Harbin Institute of Technology; Harbin 150001, P. R. China.

出版信息

J Phys Chem C Nanomater Interfaces. 2023 Feb 9;127(7):3619-3625. doi: 10.1021/acs.jpcc.2c08575. eCollection 2023 Feb 23.

DOI:10.1021/acs.jpcc.2c08575

PMID:36865992

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9969513/

Abstract

Photothermal (PT) microscopy has shown strong promise in imaging single absorbing nano-objects in soft matter and biological systems. PT imaging at ambient conditions usually requires a high laser power for a sensitive detection, which prevents application to light-sensitive nanoparticles. In a previous study of single gold nanoparticles, we showed that the photothermal signal can be enhanced more than 1000-fold in near-critical xenon compared to that in glycerol, a typical medium for PT detection. In this report, we show that carbon dioxide (CO), a much cheaper gas than xenon, can enhance PT signals in a similar way. We confine near-critical CO in a thin capillary which easily withstands the high near-critical pressure (around 74 bar) and facilitates sample preparation. We also demonstrate enhancement of the magnetic circular dichroism signal of single magnetite nanoparticle clusters in supercritical CO. We have performed COMSOL simulations to support and explain our experimental findings.

摘要

光热（PT）显微镜在对软物质和生物系统中的单个吸收性纳米物体进行成像方面显示出了巨大的潜力。在环境条件下进行光热成像通常需要高激光功率以实现灵敏检测，这限制了其对光敏感纳米颗粒的应用。在之前对单个金纳米颗粒的研究中，我们发现与典型的光热检测介质甘油相比，在近临界氙中光热信号可增强1000倍以上。在本报告中，我们表明二氧化碳（CO₂），一种比氙便宜得多的气体，能够以类似的方式增强光热信号。我们将近临界CO₂限制在细毛细管中，该毛细管能够轻松承受近临界高压（约74巴）并便于样品制备。我们还展示了在超临界CO₂中单个磁铁矿纳米颗粒簇的磁圆二色性信号增强。我们进行了COMSOL模拟以支持和解释我们的实验结果。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/4334/9969513/fc2d8bd2f7a9/jp2c08575_0002.jpg

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近临界CO₂中光热信号的千倍增强

Thousand-Fold Enhancement of Photothermal Signals in Near-Critical CO.

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