Amorphous B-doped graphitic carbon nitride quantum dots with high photoluminescence quantum yield of near 90% and their sensitive detection of Fe2+/Cd2+

Li, Bo; Zhang, Jing; Luo, Ziyu; Duan, Xinpei; Huang, Wei‐Qing; Hu, Wangyu; Pan, Anlian; Liao, Lei; Jiang, Lang; Huang, Gui‐Fang

doi:10.1007/s40843-021-1704-5

Cited by 22 publications

(17 citation statements)

References 66 publications

(97 reference statements)

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“…Recently, they went one step further by modeling the enamel from the nanoscale to the macroscale. A layer of amorphous ZrO 2 was evenly grown on the surface of the hydroxyapatite column and then assembled in an orderly manner to form an enamel-like composite, which is the closest enamel-like composite to tooth enamel so far, as shown in Figure c . Similarly, the storage modulus and damping coefficient of the artificial tooth enamel (ATE) tested by nanoindentation technology had a record high value compared with traditional engineering materials.…”

Section: Applications Of Amorphous Nanomaterialsmentioning

confidence: 99%

“…Amorphous structure provides a new opportunity to resolve the above problems, and as reported by Huang et al, the distorted structure leads to the superior elastic strain performance of amorphous boron-doped CNQDs (B-CNQDs) in a wide pH range. This will promote the mass transport and reduce exciton quenching effectively . The synthesis of stable red-emitting carbon spots is a challenge, so it is important to explore the pressure sensitivity of amorphous carbon spots. , Lu et al reported the pressure sensitivity of amorphous carbon dots, whose red-emissive amorphous carbon dots presented pressure-triggered aggregation-induced emission enhancement and reversible piezochromic luminescence, as shown in Figure d–f.…”

Section: Applications Of Amorphous Nanomaterialsmentioning

confidence: 99%

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Recent Progress of Amorphous Nanomaterials

Kang

Yang

et al. 2023

Chem. Rev.

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Amorphous materials are metastable solids with only short-range order at the atomic scale, which results from local intermolecular chemical bonding. The lack of long-range order typical of crystals endows amorphous nanomaterials with unconventional and intriguing structural features, such as isotropic atomic environments, abundant surface dangling bonds, highly unsaturated coordination, etc. Because of these features and the ensuing modulation in electronic properties, amorphous nanomaterials display potential for practical applications in different areas. Motivated by these elements, here we provide an overview of the unique structural features, the general synthetic methods, and the potential for applications covered by contemporary research in amorphous nanomaterials. Furthermore, we discussed the possible theoretical mechanism for amorphous nanomaterials, examining how the unique structural properties and electronic configurations contribute to their exceptional performance. In particular, the structural benefits of amorphous nanomaterials as well as their enhanced electrocatalytic, optical, and mechanical properties, thereby clarifying the structure−function relationships, are highlighted. Finally, a perspective on the preparation and utilization of amorphous nanomaterials to establish mature systems with a superior hierarchy for various applications is introduced, and an outlook for future challenges and opportunities at the frontiers of this rapidly advancing field is proposed.

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Section: Applications Of Amorphous Nanomaterialsmentioning

confidence: 99%

Section: Applications Of Amorphous Nanomaterialsmentioning

confidence: 99%

Recent Progress of Amorphous Nanomaterials

Kang

Yang

et al. 2023

Chem. Rev.

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“…[151] The latter is usually formed by sp 2 hybridization of nitrogen and carbon in π-conjugated graphitic planes, with both crystalline and amorphous structures. [152,153] Their bandgaps can be flexibly modified thanks to the quantum confinement effect. Graphene has a zero bandgap electronic structure, which can badly hinder its applications in catalysis and optoelectronics.…”

Section: Structure Electronic Properties and Conductivity Analysismentioning

confidence: 99%

Emerging Trends of Carbon‐Based Quantum Dots: Nanoarchitectonics and Applications

Guan

Geng

et al. 2023

Small

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“…Among the various as‐developed photocatalysts, polymeric carbon nitride (CN) has inspired intense concerns of researchers for its appropriate band structure, facile preparation, low cost, and superior chemical stability. [ 7–9 ] However, the photocatalytic activity of pristine CN was severely restricted due to the poor optical absorption and rapid recombination of photogenerated electron–hole pairs. Then a variety of strategies have been applied to improve the optical utilization and migration efficiency of charge carriers, such as morphological control, [ 10–12 ] elemental doping, [ 13,14 ] molecular engineering, [ 15,16 ] and heterostructure construction.…”

Section: Introductionmentioning

confidence: 99%

Donor–Acceptor Modification of Carbon Nitride for Enhanced Photocatalytic Hydrogen Evolution

Gao

Wan

et al. 2022

Advanced Sustainable Systems

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charge carriers, such as morphological control, [10][11][12] elemental doping, [13,14] molecular engineering, [15,16] and heterostructure construction. [17][18][19] In particular, molecular engineering is a rather effective method to regulate the chemical composition and electronic structure of CN.Efforts have been devoted to building organic conjugated copolymers with donor-acceptor system to improve the charge mobility in organic photovoltaic field. [20,21] As such, it is supposed that the construction of intramolecular D-A conjugated copolymers could be a helpful strategy to increase the photocatalytic performance of polymeric photocatalysts. Generally, the D-A conjugated copolymers could be synthesized through the copolymerization between electron donor and acceptor units. The introduction of donor or acceptor units could extend π-conjugated system and induce the intramolecular charge transfer of D-A conjugated copolymers under internal electric field, which help to facilitate the dissociation of photogenerated electrons and holes. [22][23][24][25] Moreover, the construction of D-A structure could flexibly regulate the band structure of conjugated copolymers through the pushpull effect on the highest occupied molecular orbital (HOMO) and lowest unoccupied molecular orbital (LUMO), [22,26,27] narrowing the bandgap of copolymers toward extended visiblelight absorption. For instance, Fan et al. fabricated a range of aromatics-incorporation g-C 3 N 4 -based D-A copolymer via nucleophilic substitution reactions and proposed the concept of intramolecular charge transfer transition to clarify the photo catalytic mechanism upon long-wavelength-light illumination. [24] Creatinine-derived moiety as donor unit was also incorporated into melem by copolymerization of creatinine and urea to broaden the absorption range and promote the charge spatial separation. [28] Chen et al. integrated π-deficient pyridine group with carbon nitride skeleton to modulate the electron structure, enabling tunable bandgap and boosted carrier migration. [29] Herein, modified CN-based conjugated copolymers with D-A structure were obtained by thermal copolymerization of 2-aminobenzimidazole (abIM) and urea (Figure 1a). [30,31] abIM was chosen as the reactant and serves as electron acceptor unit due to its high electron affinity. As expected, the as-prepared D-A polymeric photocatalysts with adjustable bandgap exhibit larger surface area, stronger visible-light absorption and faster charge carrier separation as compared to pristine CN. The photocatalytic hydrogen evolution rate of the optimal sample is 2566 µmol g −1 h −1 , which is ≈2.7 times that of pristine CN.The construction of conjugated copolymers with a donor-acceptor (D-A) system has emerged as a promising strategy for improving photocatalytic activity. Herein, a donor-acceptor modified carbon nitride (CN) conjugated copolymer is fabricated via facile thermal copolymerization of 2-aminobenzimidazole (abIM) and urea. The experimental results demonstrate that the abIM units are successful...

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Amorphous B-doped graphitic carbon nitride quantum dots with high photoluminescence quantum yield of near 90% and their sensitive detection of Fe2+/Cd2+

Cited by 22 publications

References 66 publications

Recent Progress of Amorphous Nanomaterials

Recent Progress of Amorphous Nanomaterials

Emerging Trends of Carbon‐Based Quantum Dots: Nanoarchitectonics and Applications

Donor–Acceptor Modification of Carbon Nitride for Enhanced Photocatalytic Hydrogen Evolution

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