Nanoparticles and Quantum Dots as Emerging Optical Sensing Platforms for Ni2+ Detection: Recent Approaches and Perspectives

Abstract

Over the preceding years, nickel (Ni) and its compounds have been increasingly employed in various aspects of human social life, metallurgical/industrial manufactures, healthcare, and chemical processes. Although Ni is considered an essential trace element in biological systems, excessive intake or metabolic deficiency of Ni2+ ions may cause detrimental health effects to living organisms. Therefore, a facile and accurate detection of Ni2+, especially in environmental and biological settings, is of huge significance. As an efficient detection method, assaying Ni2+ using optical (colorimetric and/or fluorogenic) sensors has experienced quite a vigorous growth period, with a large number of excellent research contributions. Nanomaterial-based optical sensors, including metal nanoparticles (MNPs), quantum dots (QDs), and carbon dots (CDs), offer distinct advantages over conventional small-molecule organic and inorganic sensors. This study mainly provides an overview of the recent advancements and challenges related to the design strategies of various optical nanosensors to selectively detect the Ni2+ ion. Emphasis has also been placed on comparing the sensing performance of various nanosensors, along with exploring future perspectives.