Graphdiyne nanosheets as a platform for accurate copper(ii) ion detection via click chemistry and fluorescence resonance energy transfer

Advances of functional graphdiyne in separation and detection

Separation and detection technologies are essential tools for ensuring quality, safety and efficiency across various industries. Graphdiyne (GDY), a carbon material made up of alkyne bonds conjugated with benzene rings to form a planar all-carbon network, is increasingly utilized in the fields of separation and detection. GDY is becoming an ideal separation medium due to its adjustable pore sizes, unique alkyne-rich framework, and easy to be functionalized. On the other hand, GDY shows great potential in detection with the advantages of efficient photoelectric effect, high carrier mobility, and large surface areas to provide active sites. This review summarizes the progress of functional GDY in separation and detection from 2011 to 2024. Various synthesis methods were introduced on improving the properties of GDY in separation and detection. Efforts have increasingly focused on the development of functional GDY in separation functionalities such as magnetic and membranous separations. Moreover, the application of functional GDY in detection technologies are discussed such as electrochemical, spectroanalysis, and dual-mode approaches. Finally, the promising research directions and prospects of functional GDY are discussed to explore further applications in both separation and detection.

Synthesis and Properties of Acetylenic Scaffolds Modeling Segments of 6,6,12-Graphyne

6,6,12-Graphyne is an all-carbon network formally generated by interspersing sp- and sp2-hybridized carbon atoms between the carbon hexagons of graphene. Tetraethynylethene (TEE) is one structural unit that can be identified as bridging the benzene rings in 6,6,12-graphyne. Here we present the synthesis by stepwise Sonogashira couplings of TEE scaffolds that can be considered as small model systems of 6,6,12-graphyne segments. Electrochemical studies of the scaffolds revealed that they are weaker electron acceptors than related, but smaller, radiaannulene oligomers that were previously studied as relevant model systems of other 6,6,12-graphyne segments. The connectivity of the TEE units in these acyclic oligomers plays a role for their acceptor strengths according to experiments and quantum-chemical calculations. Moreover, optical studies reveal redshifted longest-wavelength absorptions as the oligomer length increases, but only to a small degree when moving from dimer to trimer structures. Experimental results were complemented by calculated absorption and redox properties.

Cu(i)-catalysed 1,2,3-triazole stitched chalcomer assembly as Pb(ii) and Cu(ii) ion sensor: DFT and docking scrutiny

Herein, a 1,2,3-triazole derivative (CBT), synthesized using the Copper(i) catalyzed Alkyne Azide Cycloaddition (CuAAC) procedure, based on a chalcone skeleton has been reported, that was implemented as an effective sensor for Pb(ii) and Cu(ii) ions. The synthesized CBT was characterized using spectroscopic techniques such as FTIR, NMR (1H and 13C), and mass spectrometry. The sensing behaviour of CBT was analyzed using UV-Vis spectroscopy, demonstrating selective sensing for Pb(ii) and Cu(ii) ions, competitively. The correlation plot revealed the detection limit for Pb(ii) and Cu(ii) ions to be 100 μM and 110 μM respectively. In addition, DFT simulations and molecular electrostatic potential (MEP) studies scrutinized the binding strategy of the free CBT and its orientation towards the metal ions in the metal-ligand complex. The probe CBT was predicted via the online platform Way2drug for its pharmacological properties, investigating the possibility to inhibit early atherosclerosis. CBT was subsequently docked to the TRIB1 protein using AutoDock Vina and demonstrated a high binding affinity with a value of -6.2 kcal mol-1.

Graphdiyne applications in sensors: A bibliometric analysis and literature review

Graphdiyne is a two-dimensional carbon nanomaterial synthesized artificially in 2010. Its outstanding performance is considered to have great potential in different fields. This article summarizes the work of graphdiyne in the sensing field by literature summary and bibliometrics analysis. The development of graphdiyne in the field of sensing has gone through a process from theoretical calculation to experimental verification. Especially in the last three years, there has been very rapid development. The theoretical calculations suggest that graphdiyne is an excellent gas sensing material, but there is little experimental evidence in this direction. On the contrary, graphdiyne has been widely reported in the field of electrochemical sensing. At the same time, graphdiyne can also be used as a molecular switch for DNA sequencing. Fluorescent sensors based on graphdiyne have also been reported. In general, the potential of graphdiyne in sensing still needs to be explored. Current research results do not show that graphdiyne has irreplaceable advantages in sensing. The bibliometric analysis used in this review also provides cooperative network analysis and co-citation analysis on this topic. This provides a reference for the audience wishing to undertake research on the topic. In addition, according to the analysis, we also listed the direction that which this field deserves attention in the future.

Graphdiyne: from Preparation to Biomedical Applications

Graphdiyne(GDY) is a kind of two-dimensional carbon nanomaterial with specific configurations of sp and sp 2 carbon atoms. The key progress in the preparation and application of GDY is bringing carbon materials to a brand-new level. Here, the various properties and structures of GDY are introduced, including the existing strategies for the preparation and modification of GDY. In particular, GDY has gradually emerged in the field of life sciences with its unique properties and performance, therefore, the development of biomedical applications of GDY is further summarized. Finally, the challenges of GDY toward future biomedical applications are discussed.

Graphene quantum dots as nanosensor for rapid and label-free dual detection of Cu2+ and tiopronin by means of fluorescence “on–off–on” switching: mechanism and molecular logic gate

(A) Schematic diagram of the interaction and dual detection of Cu2+ and MPG by means of fluorescence “on–off–on” switching. (B) Molecular logic gate and truth table constructed based on Cu2+ and MPG as inputs and emission signal as output.