Sustainable applications of carbon dots-based composites as photocatalyst for environmental pollutants remediation

Abidin, Zurina Zainal; Pudza, Musa Yahaya; Issa, Mohammed; Zentou, Hamid; Harun, Nur Haninah; Halim, Noor Amirah Abdul

doi:10.1016/b978-0-323-91894-7.00021-9

Cited by 1 publication

(2 citation statements)

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“…This technique has shown promise for synthesizing high-end nanomaterials like graphene quantum dots (GQDs) from biodegradable wastes such as citric acid, 33−36 tapioca, 37 flour, 38,39 cellulose-based, 40,41 and other materials. 42 Additionally, recent studies have reported the synthesis of nonpolar GQDs using acid/base-free microwave pyrolysis. 43 The nonpolar GQDs synthesized using microwave pyrolysis exhibited exceptional physicochemical attributes, which ultimately gave superior self-cleaning efficacy and durability for their application as a coating onto cotton fabric.…”

Section: Introductionmentioning

confidence: 99%

“…These diverse applications showcase the versatility of pyrolysis in transforming waste materials into structurally distinct carbon-based materials, highlighting its potential as a sustainable and controlled synthesis method. This technique has shown promise for synthesizing high-end nanomaterials like graphene quantum dots (GQDs) from biodegradable wastes such as citric acid, − tapioca, flour, , cellulose-based, , and other materials . Additionally, recent studies have reported the synthesis of nonpolar GQDs using acid/base-free microwave pyrolysis .…”

Section: Introductionmentioning

confidence: 99%

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Hydrothermal Pyrolysis of Styrofoam Waste for Efficient Copper Ion Sensing Using Graphene Quantum Dots

Kumar,

Rani,

Mathew

et al. 2024

ACS Sustainable Resour. Manage.

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The accelerating buildup of plastic waste, especially styrene foam, has become a major environmental problem. Traditional methods of recycling do not help in managing Styrofoam waste efficiently because of economic factors and minimal technological advancements available. Pyrolysis is one of the promising ways to transform styrenofoam wastes into value-added compounds with nominal emission of harmful gases. This research aims to explore the synthesis of graphene quantum dots (GQDs) from Styrofoam waste through hydrothermal pyrolysis and convert it into a high-utility, value-added product. The successful formation of GQDs was confirmed through multiple characterization techniques: transmission electron microscopy revealed a uniform size distribution of 6 ± 1 nm; dynamic light scattering confirmed all GQD samples were below 10 nm; Raman spectroscopy identified the presence of a single-layered graphene structure; and X-ray photoelectron spectroscopy demonstrated the incorporation of nitrogen and oxygen functionalities. The quantum yield of GQDs increased with increase in reaction temperature and the edge functionalities, giving a peak value of 1.87 as confirmed using photoluminescence and UV-Vis spectroscopy, indicating their suitability for enhanced optical performance. The synthesized GQDs were explored as sensors for the detection of heavy metal ions in water. The sensor showed versatility and efficacy for copper ions across different pH levels, water sources, and anions present in various copper salts. Ultimately the concentration of unknown copper ion solutions was calculated from GQD-sensor-based RGB studies, matching closely with UV-Vis spectroscopy values of the unknown solutions. This work demonstrates a promising approach for the pyrolysis-based treatment of plastic waste, contributing to waste management and sustainability efforts.

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