Themed collection Graphyne

With unique sp-, sp²-hybridized carbon atoms, natural band gap, highly conjugated π electrons and uniform pore structure, graphdiyne (GDY) has been receiving increased attention and is predicted to have good application prospects in many fields.

This review has comprehensively reviewed the graphdiyne-based catalysts for broad applications in electrochemical processes and energy storage devices, which will supply significant references for future research in this field.

Graphdiyne features a high π-conjugation degree and an intrinsic natural bandgap, which guarantee a large optical refractive index and broadband absorption, and thus promises a wide range of application prospects in nonlinear optics.

Theoretical exploration accelerates the design of robust and efficient graphyne-based advanced energy and electronic devices for real applications.

A modified interface synthesis was developed for fast preparation of graphyne derivates that are comprised of aza-aromatics and acetylenic linkers, providing some reference for understanding the properties of graphyne-based versatile materials.

The sp-hybridized nitrogen atoms (sp-N) have been site-specifically doped into graphdiyne (GDY). The precisely constructed sp-N doped GDY displays superior electrocatalytic activity for Zn–air batteries.

Graphdiyne oxide-doped SnO₂ is applied as a novel electron transfer layer for the preparation of high-performance perovskite devices.

Composite catalysts of 3D sponge-like porous Pyr-GDY anchored capping agent free ultrafine Ag NPs were constructed, which displayed a record-high catalytic activity towards solvent-free CO₂ cycloaddition with propargylamines.

The well-dispersed and biosafe hemin/graphdiyne (GDY) nanocomposite (GDY–hemin) exhibits high peroxidase activity, which can decompose H₂O₂ to generate highly-toxic hydroxyl radicals, leading to bacterial death in both in vitro and in vivo.

A photoactive conjugated polymer/graphdiyne nanocatalyst was developed for the in situ reduction of CO₂ to CO for hypoxia tumor treatment.

MnO₂@GDYO hybrid 3D nanoflowers have been designed and fabricated via the in situ growth of MnO₂ in graphdiyne oxide nanosheets in aqueous solution. This work brings new prospects for the design of GDYO hybrids for high-performance aqueous ZIBs.

A new GDY@NiO_x(OH)_y heterostructure was synthesized by creatively incorporating GDY with NiO_x(OH)_y for efficient water splitting. The mixed valence states and facilitated charge transfer behavior significantly improve the catalytic activity.

Co-Loaded porphyrin-graphdiyne (CoPor-GDY) as a bifunctional electrocatalyst for HER and OER.

Developing highly active, stable and low-cost electrocatalysts capable of an efficient oxygen evolution reaction (OER) is urgent and challenging.

3D acetylenic bonds distributing makes tetraphenyl methane substitute graphdiyne (TPM-GDY) show more active sites and high hydrogen evolution reaction performance.