Fluorescence-based sensors as an emerging tool for anion detection: mechanism, sensory materials and applications

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Abstract

Negatively charged ions are integral parts of our ecosystem. Fluorescence-based approaches show great promise in terms of developing efficient sensing platforms for anion detection.

Abstract

Negatively charged ions are an integral part of our ecosystem, where at certain concentrations (fixed by the Environmental Protection Agency (EPA) and World Health Organization (WHO)), they are non-toxic. However, with an increase or decrease in their concentration due to pollution, industrialization, etc., anions show harmful effects. Therefore, the detection of anions with high sensitivity and selectivity is necessary, which is challenging. In the past few years, various fluorescence-based sensory materials have been developed to detect anions in the solution, solid, and vapor phases through various mechanisms. Significant undertakings are in progress to develop fluorescent materials with high sensitivity, selectivity, and fast response time. This review article starts with the various sensing mechanisms for fluorescence-based anion detection. Subsequently, the fluorescent sensory materials for anion detection are widely and efficiently summarized, focusing on the last 10 years of investigation. The focus of this review is to present a broad scope of fluorescent materials, for example, supramolecular systems, polymeric chemosensors, small molecules, metal–organic frameworks (MOFs), and aggregation-induced emissive materials, and their associated mechanisms and applications. Also, an outline of the reported fluorescent materials and their mechanism, anion detection, low detection limit (LOD), and applications are presented in a table format.

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Hiroki Uoyama, Kenichi Goushi, Katsuyuki Shizu … (2012)

The inherent flexibility afforded by molecular design has accelerated the development of a wide variety of organic semiconductors over the past two decades. In particular, great advances have been made in the development of materials for organic light-emitting diodes (OLEDs), from early devices based on fluorescent molecules to those using phosphorescent molecules. In OLEDs, electrically injected charge carriers recombine to form singlet and triplet excitons in a 1:3 ratio; the use of phosphorescent metal-organic complexes exploits the normally non-radiative triplet excitons and so enhances the overall electroluminescence efficiency. Here we report a class of metal-free organic electroluminescent molecules in which the energy gap between the singlet and triplet excited states is minimized by design, thereby promoting highly efficient spin up-conversion from non-radiative triplet states to radiative singlet states while maintaining high radiative decay rates, of more than 10(6) decays per second. In other words, these molecules harness both singlet and triplet excitons for light emission through fluorescence decay channels, leading to an intrinsic fluorescence efficiency in excess of 90 per cent and a very high external electroluminescence efficiency, of more than 19 per cent, which is comparable to that achieved in high-efficiency phosphorescence-based OLEDs.

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Jingdong Luo, Zhiliang Xie, Jacky W. Y. Lam … (2001)

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Luminescent metal-organic frameworks for chemical sensing and explosive detection.

Zhichao Hu, Benjamin Deibert, Jing-Jing Li (2014)

Metal-organic frameworks (MOFs) are a unique class of crystalline solids comprised of metal cations (or metal clusters) and organic ligands that have shown promise for a wide variety of applications. Over the past 15 years, research and development of these materials have become one of the most intensely and extensively pursued areas. A very interesting and well-investigated topic is their optical emission properties and related applications. Several reviews have provided a comprehensive overview covering many aspects of the subject up to 2011. This review intends to provide an update of work published since then and focuses on the photoluminescence (PL) properties of MOFs and their possible utility in chemical and biological sensing and detection. The spectrum of this review includes the origin of luminescence in MOFs, the advantages of luminescent MOF (LMOF) based sensors, general strategies in designing sensory materials, and examples of various applications in sensing and detection.