Functional ZnS:Mn(II) quantum dot modified with L-cysteine and 6-mercaptonicotinic acid as a fluorometric probe for copper(II)

Wang, Jiangru; Yu, Jialuo; Wang, Xiaoyan; Wang, Liyan; Li, Bowei; Shen, Dazhong; Kang, Qi; Chen, Lingxin

doi:10.1007/s00604-018-2952-x

Cited by 27 publications

(21 citation statements)

References 36 publications

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“…CQDs capable of easy functionalization, tunable PL, etc., portray diverse sensing applications. [ 274 ] The nonblinking PL capability enables tracking of single molecules and thus CQDs have been proved to be instrumental for the detection of heavy metal ions (Cr 6+/3+ , [ 90,275,276 ] Hg 2+ , [ 61,220,277–281 ] Fe 2+ , [ 23,113 ] Cu 2+ , [ 282–285 ] Ag +[ 286 ] ), anions (I − , [ 278 ] NO 2 − , [ 287 ] F − , [ 278 ] S 2 O 3 2− , [ 288 ] ClO −[ 289 ] ), small molecules (thrombin, [ 290 ] hyaluronidase, [ 291 ] glyphosate, [ 292 ] glucose, [ 56,127 ] H 2 O 2 , [ 49,56,285,293 ] dopamine, [ 70 ] tannic acid, [ 294 ] uric acid, [ 193 ] glycine, [ 295 ] ), temperature, [ 70 ] and pH [ 296,297 ] over the years. The capability of CQD to take up the dual roles of electron source and sink is the major reason for the fluorescent detections.…”

Section: Applicationsmentioning

confidence: 99%

Doping and Surface Modification of Carbon Quantum Dots for Enhanced Functionalities and Related Applications

John

Nair

2021

Part & Part Syst Charact

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Carbon quantum dots (CQDs) are a unique class of 0D nanomaterials, featured by a graphitic core and shell layers saturated with hydrogen atoms and functional groups. CQDs are prepared through top‐down and bottom‐up strategies from natural and synthetic precursors. CQDs can be modified through chemical (e.g., surface functionalization/passivation, doping, etc.) and physical (e.g., core–shell architecture, composite material blending, etc.) strategies to control their properties. This review highlights the effect of such modifications on the photophysical properties of CQDs, such as photoluminescence (PL), absorbance, and relaxivity. The dependence of PL upon the size, orientation at the edges, surface and edge functionalization, doping, excitation wavelength, concentration, pH, aggregate formation, etc., are summarized along with the supporting theoretical evidence available in the literature. Also, this review outlines the recent advancements, and future prospective of optical (e.g., sensing, bioimaging, and fluorescent ink) and catalytic applications (e.g., photocatalysis and electrocatalysis) of CQDs enhanced through physical and chemical modifications of their structure and composition.

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Section: Applicationsmentioning

confidence: 99%

Doping and Surface Modification of Carbon Quantum Dots for Enhanced Functionalities and Related Applications

John

Nair

2021

Part & Part Syst Charact

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“…Very promising research is done in this field, with novel approaches outside of polymeric OSPs; i.e. by using surface modified magnetic beads [139] or quantum dots [140]; just to name a few.…”

Section: Conclusion Current Challenges and Future Prospectivementioning

confidence: 99%

Nanoparticle- and microparticle-based luminescence imaging of chemical species and temperature in aquatic systems: a review

et al. 2019

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Most aquatic systems rely on a multitude of biogeochemical processes that are coupled with each other in a complex and dynamic manner. To understand such processes, minimally invasive analytical tools are required that allow continuous, real-time measurements of individual reactions in these complex systems. Optical chemical sensors can be used in the form of fiber-optic sensors, planar sensors, or as micro-and nanoparticles (MPs and NPs). All have their specific merits, but only the latter allow for visualization and quantification of chemical gradients over 3D structures. This review (with 147 references) summarizes recent developments mainly in the field of optical NP sensors relevant for chemical imaging in aquatic science. The review encompasses methods for signal read-out and imaging, preparation of NPs and MPs, and an overview of relevant MP/NP-based sensors. Additionally, examples of MP/NP-based sensors in aquatic systems such as corals, plant tissue, biofilms, sediments and watersediment interfaces, marine snow and in 3D bioprinting are given. We also address current challenges and future perspectives of NP-based sensing in aquatic systems in a concluding section.

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“…To overcome the aforementioned shortcomings, alternative assay systems should possess rapid, accuracy, visible and cost effective merits. Tremendous portable probes with the convenient simple operation have been extended based on fluorescent and colorimetric nanomaterials, such as carbon dots, [11] quantum dots, [12] silicon nanoparticles, [13] metal nanoparticles. [14] Metal nanoparticle-based (such as gold (Au), silver (Ag) nanoparticles) sensing systems have been developed for detecting the levels of ions and biomolecules in environmental and biological samples due to possessing unique optical properties surface plasmon resonance (SPR).…”

Section: Introductionmentioning

confidence: 99%

Silver Nanoparticles for Colorimetric Detection and Discrimination of Mercury Ions in Lake Water

Zou

Pang

Zhang³

et al. 2021

ChemistrySelect

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As the most toxic heavy metal, mercury (Hg) has been considered as the greatest environmental threat and it reach ubiquitous in industrial waste water and extended to environment. The detection of Hg 2 + in environmental water is a crucial work for both protecting the environment and human health. Colorimetric assay exhibits visual discriminating and simple readout. This work presents the selective sensing of metal ion (Hg 2 + ) by silver particles (Ag NPs), which were functionalized by galactosamine and synthesized via simple one pot method, with the average particle diameter of 18.75 � 0.49 nm. The limit of detection (LOD) was calculated as low as 7.92 nM. The colorimetric probe can also be performed in real water sample with good selectivity, and recovery was found to be 95-102 %, indicating can be used for on-line determination of Hg 2 + in the complex aqueous solutions. Additionally, the good catalytic performance of Ag NPs was demonstrated by hydrogenation of p-nitrophenol and potassium ferricyanide in water samples.

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Functional ZnS:Mn(II) quantum dot modified with L-cysteine and 6-mercaptonicotinic acid as a fluorometric probe for copper(II)

Cited by 27 publications

References 36 publications

Doping and Surface Modification of Carbon Quantum Dots for Enhanced Functionalities and Related Applications

Doping and Surface Modification of Carbon Quantum Dots for Enhanced Functionalities and Related Applications

Nanoparticle- and microparticle-based luminescence imaging of chemical species and temperature in aquatic systems: a review

Silver Nanoparticles for Colorimetric Detection and Discrimination of Mercury Ions in Lake Water

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