Quantum yield optimization of carbon dots using response surface methodology and its application as control of Fe³⁺ion levels in drinking water

Abstract: Early detection of heavy metals in drinking water is a fundamental step that must be taken to prevent adverse effects on health. This research aims to develop a heavy metal ion detector by utilizing the fluorescence properties of carbon dots. Cdots were synthesized using the microwave irradiation method based on the central composite design: urea mass 0.31-3.68 gr; reactor power 200-1000 W; synthesis time is 13-46 min, and the response is quantum yield. Material characterization includes PL, TEM, UV-VIS, XRD, … Show more

“…The quantum yield of these C-dots was gauged against quinine sulfate (used as a reference with an excitation wavelength of 410 nm). 25 Boasting a fluorescence quantum yield of 12.5%, these C-dots either matched or surpassed the yields of some previously documented C-dots.…”

A novel method for synthesis of carbon dots and their applications in reactive oxygen species (ROS) and glucose detections

“…The quantum yield of these C-dots was gauged against quinine sulfate (used as a reference with an excitation wavelength of 410 nm). 25 Boasting a fluorescence quantum yield of 12.5%, these C-dots either matched or surpassed the yields of some previously documented C-dots.…”

A novel method for synthesis of carbon dots and their applications in reactive oxygen species (ROS) and glucose detections

“…Previous studies have demonstrated a close correlation between quantum dots' antioxidant properties, iron-chelating ability, their sp²-hybridized carbon cluster structure, and surface functional groups such as hydroxyl, carbonyl, and amino groups [11][12][13]. We detailedly characterized the surface functional groups and elemental composition of ginsenoside Rb1 and RBCQDs using fourier-transform infrared spectroscopy (FTIR) and X-ray photoelectron spectroscopy (XPS).…”

Carbon Quantum Dots of Ginsenoside Rb1 for Application in a Mouse Model of Intracerebral Hemorrhage

“…The addition of metal ions to the SQDs causes the formation of a non-fluorescent complex between SQDs and metal ions. 78 The quantum yield of the SQDs reflects that these non-fluorescent complexes grow as the metal ion concentration rises and that the fluorescence emission at the maximal excitation wavelength gradually decreases. Even the TRPL measurements support the static mechanism, i.e., the complex formation between the metal ions and SQDs.…”

Dual functions of metal ion detection and antibacterial activity of sulfur quantum dots