Citric Acid Derived Carbon Dots, the Challenge of Understanding the Synthesis-Structure Relationship

Carbon dots (CDs) are highly-emissive nanoparticles obtained through fast and cheap syntheses. The understanding of CDs' luminescence, however, is still far from being comprehensive. The intense photoluminescence can have different origins: molecular mechanisms, oxidation of polyaromatic graphene-like layers, and core-shell interactions of carbonaceous nanoparticles. The citric acid (CA) is one of the most common precursors for CD preparation because of its high biocompatibility, and this review is mainly focused on CA-based CDs. The different parameters that control the synthesis, such as the temperature, the reaction time, and the choice of solvents, were critically described. Particular attention was devoted to the CDs' optical properties, such as tunable emission and quantum yields, in light of functional applications. The survey of the literature allowed correlating the preparation methods with the structures and the properties of CA-based CDs. Some basic rules to fabricate highly luminescent nanoparticles were selected by the metanalysis of the current literature in the field. In some cases, these findings can be generalized to other types of CDs prepared via liquid phase.

Automated summary

Carbon dots (CDs) are highly-emissive nanoparticles obtained through fast and cheap syntheses, with various origins for their luminescence mechanisms. Citric acid is a common precursor for CD preparation, and factors such as temperature, reaction time, and solvent choice play critical roles in synthesis control. The focus on CDs' optical properties, tunable emissions, and quantum yields, is essential for functional applications, while basic rules for fabricating highly luminescent nanoparticles can be derived from literature metanalysis.