Kalium‐Polyheptazinimid: Ein übergangsmetallfreier Festkörper‐Triplett‐Sensibilisator in Kaskadenenergietransfer und [3+2]‐Cycloadditionen

Savateev, Aleksandr; Tarakina, Nadezda V.; Strauß, Volker; Hussain, Tanveer; Brummelhuis, Katharina ten; Vadillo, José Manuel Sánchez; Markushyna, Yevheniia; Mazzanti, Stefano; Tyutyunnik, А. P.; Walczak, Ralf; Oschatz, Martin; Guldi, Dirk M.; Karton, Amir; Antonietti, Markus

doi:10.1002/ange.202004747

Cited by 28 publications

(40 citation statements)

References 64 publications

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“…[ 42 ] As is indeed the case in this study, cooling the sample splits the reflection corresponding to d = 1.65 Å into two peaks as indicative of symmetry being reduced from a strictly planar hexagonal space group, and the best structural model from subsequent Rietveld refinement shows slight non‐planarity in the triazine layers. For PHI as another example, describing the stacking structure is one problem [ 44 ] that can be tackled by combined PDF and XRD analyses, which show how its pore constituents—the water molecules and potassium ions—mediate the stacking of the PHI layers in the 3D. [ 29d ] Here, within the pores of the PHI, the water‐solvated potassium cations as incorporated from the salt melt synthesis strongly interact with the PHI layers, providing a directing effect on the layer stacking resulting in slip‐stacked layers; conversely, removal of these cations (e.g., by exchange with protons) leads to more defective stacking owing to the weaker interactions between the PHI layers.…”

Section: Characterization Methodologies From Molecular Structure To O...mentioning

confidence: 99%

A Tour‐Guide through Carbon Nitride‐Land: Structure‐ and Dimensionality‐Dependent Properties for Photo(Electro)Chemical Energy Conversion and Storage

Lau

Lotsch

2021

Advanced Energy Materials

108

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Antonietti and coworkers on its photocatalytic properties in 2009. [1] Originally a niche subject of academic curiosity from the works of Berzelius, Liebig, [2] and Gmelin [3] nearly 200 years ago, interests in this material family was first revived as a proposed precursor to the computationally postulated ultrahard ß-C 3 N 4 in the 1990s. [4] In the last decade, the surge in publications on g-C 3 N 4 materials arose primarily due to their favorable photo-/electro-chemical properties, especially for the photocatalytic synthesis of solar fuels such as hydrogen from water-splitting, a research direction motivated by concerns over the environmental and socio-political impacts of our reliance on fossil fuels. Many of these publications focus on the catalytic aspects of this class of materials, aiming to improve their reaction kinetics through chemical modification or material processing. In

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Section: Characterization Methodologies From Molecular Structure To O...mentioning

confidence: 99%

A Tour‐Guide through Carbon Nitride‐Land: Structure‐ and Dimensionality‐Dependent Properties for Photo(Electro)Chemical Energy Conversion and Storage

Lau

Lotsch

2021

Advanced Energy Materials

108

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“…The PHI layers are aligned directly on top of each other forming continuous channels along the c direction (AAA stacking). [ 6 ] Analysis of both HR‐TEM and SAED data shows that nanocrystalline domains tend to be preferentially oriented in the flack along the c direction of the structure, but possess rotational disorder in the ab plane.…”

Section: Resultsmentioning

confidence: 99%

“…This approach facilitates the investigation of the complementary oxidation/reduction reaction (e.g., proton reduction to H 2 and water oxidation to O 2 ). [ 4 ] The scavenging process can, however, create a strong kinetic asymmetry in the carrier extraction from the light absorber, resulting in the accumulation of one type of charge, [ 5,6 ] as detailed in Figure . This charge accumulation process may generate bottlenecks in the hydrogen evolution reaction (HER) photocatalyzed by carbon nitride‐based materials.…”

Section: Introductionmentioning

confidence: 99%

Overcoming Electron Transfer Efficiency Bottlenecks for Hydrogen Production in Highly Crystalline Carbon Nitride‐Based Materials

Teixeira

Tarakina

Silva

et al. 2022

Advanced Sustainable Systems

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challenging, it is undeniable that it will have an essential role in the replacement of fossil fuels in the future. Nonfossil hydrogen sources will be essential to make CO 2 reduction technology sustainable, since nowadays 96% of commercial hydrogen comes from fossil fuels. [2] Among the renewable sources of hydrogen gas, certainly, sun-light-driven water splitting is one of the most promising. The fundamental steps of efficient photocatalytic water splitting include photon absorption, charge separation, and transfer of photogenerated electrons and holes to electrochemical interfaces to drive surface chemistry, such as the formation of the HH bond after proton reduction. [3] Commonly, in studies that deal with water splitting photocatalyzed by semiconductors, hole or electron scavengers are often added to remove one charge carrier efficiently from the photocatalyst. This approach facilitates the investigation of the complementary oxidation/reduction reaction (e.g., proton reduction to H 2 and water oxidation to O 2 ). [4] The scavenging process can, however, create a strong kinetic asymmetry in the carrier extraction from the light absorber, resulting in the accumulation of one type of charge, [5,6] as detailed in Figure 1. This charge accumulation process may generate bottlenecks in the hydrogen evolution reaction (HER) photocatalyzed by carbon nitride-based materials. As demonstrated by Durrant and co-workers the trapped charges promote an increment in the e − /h + recombination rate constant (k 3 ), resulting in lower performance. However, this is only one of the possible limiting steps in the HER, and we will show that current limitations are also beyond the interface of the semiconductor.Recently, carbon nitride-based materials have attracted attention due to their many merits in terms of visible light response, [7] easy-modified textural/electronic structure, [8,9] and great photochemical stability. [8,10] Although polymeric carbon nitride (PCN) standing out as the most investigated carbon nitride-based material in the HER, unfortunately, pure PCN, without modification/ optimization of its structure and properties, displays a very limited activity even in the presence of scavengers. [11] The synthesis of carbon nitride materials in the presence of an inorganic salt, such as NaCl, KCl, and LiCl, which can be molten or not in the synthesis conditions, lead to a range of highly ordered carbon nitride-based materials with improved efficiency in the HER. [12]

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“…It is likely that Equation (6) overestimates real S SA of materials, since it does not take into account possible sintering of particles. If not available in the reference article, the following gravimetric density of materials was used: ZnO 5.6 g cm −3 , TiO 2 3.9 g cm −3 (amorphous, anatase), K‐PHI 1.88 g cm −3 (X‐ray density), [ 39 ] H‐PHI 1.39 g cm −3 (X‐ray density), [ 38 ] gCN (when crystal structure was not explicitly specified) 2.2 g cm −3 , In 2 O 3 6.75 g cm −3 , CeO 2‐ x 7.13 g cm −3 , CdSe 5.3 g cm −3 , and WO 3 7.2 g cm −3 . Gravimetric density of hybrid composites made of SCPs and metal nanoparticles or two semiconductors was calculated taking into account a fraction and gravimetric density of each component.…”

Section: Database Of Photocharged Materialsmentioning

confidence: 99%

“…determined that in potassium poly(heptazine imide) (K‐PHI, Figure 3b) K + ions are located closer to the center of the channels and in between layers. [ 39 ] Sahoo et al. modeled structures of several metal poly(heptazine imide)s and found that in K‐PHI and Mg‐PHI cations are in the pores between the layers, while in Au‐PHI and Ru‐PHI cations are in the same plane with PHI layer.…”

Section: Introductionmentioning

confidence: 99%

Photocharging of Semiconductor Materials: Database, Quantitative Data Analysis, and Application in Organic Synthesis

Savateev

2022

Advanced Energy Materials

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Kalium‐Polyheptazinimid: Ein übergangsmetallfreier Festkörper‐Triplett‐Sensibilisator in Kaskadenenergietransfer und [3+2]‐Cycloadditionen

Cited by 28 publications

References 64 publications

A Tour‐Guide through Carbon Nitride‐Land: Structure‐ and Dimensionality‐Dependent Properties for Photo(Electro)Chemical Energy Conversion and Storage

A Tour‐Guide through Carbon Nitride‐Land: Structure‐ and Dimensionality‐Dependent Properties for Photo(Electro)Chemical Energy Conversion and Storage

Overcoming Electron Transfer Efficiency Bottlenecks for Hydrogen Production in Highly Crystalline Carbon Nitride‐Based Materials

Photocharging of Semiconductor Materials: Database, Quantitative Data Analysis, and Application in Organic Synthesis

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