Response of Photonic Hydrogels of Homogeneous Particles to Uranyl Ions in Aqueous Solutions

IF 5 2区 物理与天体物理 Q1 INSTRUMENTS & INSTRUMENTATION Photonic Sensors Pub Date : 2023-09-27 DOI:10.1007/s13320-023-0695-8
R. G. Joshi, Deepak K. Gupta, P. Amesh, P. K. Parida, T. R. Ravindran
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Abstract

Abstract We study here the response of photonic hydrogels (PHs), made of photonic crystals of homogeneous silica particles in polyacrylamide hydrogels (SPHs), to the uranyl ions UO 2 2+ in aqueous solutions. It is found that the reflection spectra of the SPH show a peak due to the Bragg diffraction, which exhibits a blue shift in the presence of UO 2 2+ . Upon exposure to the SPH, UO 2 2+ gets adsorbed on the SPH and forms complex coordinate bonds with multiple ligands on the SPH, which causes shrinking of hydrogel and leads to the blue shift in the diffraction peak. The amount of the blue shift in the diffraction peak increases monotonically up to UO 2 2+ concentrations as high as 2300µM. The equilibration time for the shift in the Bragg peak upon exposure to UO 2 2+ is found to be ~30 min. These results are in contrast to the earlier reports on photonic hydrogels of inhomogeneous microgel particles hydrogel (MPH), which shows the threshold UO 2 2+ concentration of ~600 µM, below which the diffraction peak exhibits a blue shift and a change to a red shift above it. The equilibration time for MPH is ~300min. The observed monotonic blue shift and the faster time response of the SPH to UO 2 2+ as compared to the MPH are explained in terms of homogeneous nature of silica particles in the SPH, against the porous and polymeric nature of microgels in the MPH. We also study the extraction of UO 2 2+ from aqueous solutions using the SPH. The extraction capacity estimated by the arsenazo-III analysis is found to be 112 mM/kg.
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均匀粒子光子水凝胶对水溶液中铀酰离子的响应
摘要本文研究了聚丙烯酰胺水凝胶(SPHs)中均相二氧化硅粒子的光子晶体构成的光子水凝胶(PHs)对水溶液中铀酰离子UO 22 +的响应。发现SPH的反射光谱在uo22 +的存在下,由于Bragg衍射而出现了一个蓝移峰。暴露于SPH后,UO 22 +被吸附在SPH上,与SPH上的多个配体形成复杂的配位键,导致水凝胶收缩,导致衍射峰蓝移。当u22 +浓度高达2300µM时,衍射峰的蓝移量单调增加。暴露于UO 22 +后,Bragg峰位移的平衡时间为~30 min。这些结果与先前关于非均匀微凝胶粒子水凝胶(MPH)的光子水凝胶的报道相反,该结果显示UO 22 +浓度的阈值为~600µM,低于该阈值的衍射峰呈现蓝移,而高于该阈值的衍射峰则呈现红移。MPH的平衡时间为~300min。观察到的单调蓝移和SPH对UO 22 +比MPH更快的时间响应可以解释为SPH中二氧化硅颗粒的均匀性,而MPH中微凝胶的多孔性和聚合性。我们还研究了用SPH从水溶液中萃取u22 +。偶氮胂-ⅲ的萃取量为112 mM/kg。
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来源期刊
Photonic Sensors
Photonic Sensors Physics and Astronomy-Atomic and Molecular Physics, and Optics
CiteScore
8.60
自引率
2.30%
发文量
270
审稿时长
13 weeks
期刊介绍: Photonic Sensors publishes original, peer-reviewed articles that report on new developments of interest to both the photonics and sensor communities in all fields of photonic sensing science and technology. Topics include optical fiber sensors, planar waveguide sensors, laser-based sensors, and biophotonic sensors, etc. Photonic Sensors focuses on experimental contributions related to novel principles, structures or materials for photonic sensors. Papers that report on investigations based on combinations of experimental and analytical/numerical approaches are also welcome.
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