Strongly Reducing (Diarylamino)benzene-Based Covalent Organic Framework for Metal-Free Visible Light Photocatalytic H₂O₂ Generation

Abstract: Photocatalytic reduction of molecular oxygen is a promising route toward sustainable production of hydrogen peroxide (H 2 O 2 ). This challenging process requires photoactive semiconductors enabling solar energy driven generation and separation of electrons and holes with high charge transfer kinetics. Covalent organic frameworks (COFs) are an emerging class of photoactive semiconductors, tunable at a molecular level for high charge carrier generation and transfer.… Show more

“…When the light was switched on, in situ grafted surface >OH groups served as hole traps to produce H + as shown in Eq. (9)- (12). The pH was quickly reduced and reached 4.38 in the spontaneous ACNT-5 system; this pH is even lower than that of the CN system with a sacrificial agent (pH = 5.10) due to lower hydroxyl radical production.…”

“…Semiconductor photocatalytic reduction of O2 in H2O to produce H2O2 provides an alternative and viable approach [9][10][11][12][13]. For example, Teranishi et al utilized a hybrid photocatalyst, Au/TiO2, for H2O2 production [14], while Kim et al used a graphene oxide/CdS hybrid composite to produce H2O2 by harnessing low-energy photons (635 nm) [15].…”

Carbon nitride nanotubes with in situ grafted hydroxyl groups for highly efficient spontaneous H2O2 production

“…When the light was switched on, in situ grafted surface >OH groups served as hole traps to produce H + as shown in Eq. (9)- (12). The pH was quickly reduced and reached 4.38 in the spontaneous ACNT-5 system; this pH is even lower than that of the CN system with a sacrificial agent (pH = 5.10) due to lower hydroxyl radical production.…”

“…Semiconductor photocatalytic reduction of O2 in H2O to produce H2O2 provides an alternative and viable approach [9][10][11][12][13]. For example, Teranishi et al utilized a hybrid photocatalyst, Au/TiO2, for H2O2 production [14], while Kim et al used a graphene oxide/CdS hybrid composite to produce H2O2 by harnessing low-energy photons (635 nm) [15].…”

Carbon nitride nanotubes with in situ grafted hydroxyl groups for highly efficient spontaneous H2O2 production

“…Recently, COFs have emerged as potential candidates for several photocatalytic transformations. [138][139][140][141] Pachfule et al, 138 showed that a crystalline diacetylene functionalized COF performs better than its amorphous counterpart in photocatalytic hydrogen evolution reaction. Hence, it is clear that crystallinity is a crucial component in improving the charge carrier separation and transfer kinetics.…”

Conquering the crystallinity conundrum: efforts to increase quality of covalent organic frameworks

“…[10] Due to their extensive tailorability and attractiveness for av ast range of applications,t he structural design of MOFs and COFs has formed av ery active field of research. [11][12][13][14][15] Thanks to am eticulous control over synthesis conditions and an ever-expanding versatile set of experimentally available building blocks,i th as even become possible to synthesize combinations of building blocks in different structures.T of ully explore the functionalities of the enormous amount of potential structures that can be formed from agiven set of building blocks,anaccurate protocol is needed to systematically derive structural models for these materials at realistic working conditions of temperature and pressure. [16,17] Such structural characterization is ac onditio sine qua non for the atomically guided design of functional applications in the fields of catalysis,sorption, light harvesting and more.…”

“…Within this toolbox lies the concept of reticular design, [8] where judiciously chosen building blocks are assembled in a predesigned topology, giving rise to materials such as metal‐organic frameworks (MOFs) [9] and covalent organic frameworks (COFs) [10] . Due to their extensive tailorability and attractiveness for a vast range of applications, the structural design of MOFs and COFs has formed a very active field of research [11–15] . Thanks to a meticulous control over synthesis conditions and an ever‐expanding versatile set of experimentally available building blocks, it has even become possible to synthesize combinations of building blocks in different structures.…”

Quantifying the Likelihood of Structural Models through a Dynamically Enhanced Powder X‐Ray Diffraction Protocol