Graphene Domain Signature of Raman Spectra of sp2 Amorphous Carbons

Sheka, E. F.; Golubev, Yevgeny A.; Popova, Nadezhda A.

doi:10.3390/nano10102021

Cited by 56 publications

(61 citation statements)

References 88 publications

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“…Therefore, having been known for more than one-and-a-half thousand years, amorphous carbon is undergoing a rebirth and appears as agglomerative compositions of framed graphene molecules, thus becoming a special subject of modern nanotechnology. A recent extended study was devoted to a detailed investigation of the structure and chemical composition of amorphous carbons of the highest carbonization [79][80][81][82]. For the first time, reasonable models of graphene molecules, which are the basic structural units (BSUs) of the studied solids and which correspond to both their structure and chemical composition, including a definite C:O:H atom relation, were suggested.…”

Section: Spin Nature Of the Reaction Final Productsmentioning

confidence: 99%

“…Bright spots on the N DA distribution maps reveal the radical character of the species. Later on, the models were corrected based on IR reflection [81] and Raman scattering [82] data. The correction concerned the structure-chemical pattern of the heteroatom distribution around the pristine (5,5) NGr molecule, keeping the relation of C:O:H components fixed and the radical character of the models conserved.…”

Section: Spin Nature Of the Reaction Final Productsmentioning

confidence: 99%

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sp2 Carbon Stable Radicals

Sheka

2021

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sp2 Nanocarbons such as fullerenes, carbon nanotubes, and graphene molecules are not only open-shell species, but spatially extended, due to which their chemistry is quite specific. Cogently revealed dependence of the final products composition on size and shape of the carbons in use as well as on the chemical prehistory is accumulated in a particular property—the stabilization of the species’ radical efficiency, thus providing the matter of stable radicals. If the feature is highly restricted and rarely available in ordinary chemistry, in the case of sp2 nanocarbons it is just an ordinary event providing, say, tons-in-mass stable radicals when either producing such widely used technological products as carbon black or dealing with deposits of natural sp2 carbons such as anthracite, shungite carbon, and other. Suggested in the paper is the consideration of stable radicals of sp2 nanocarbons from the standpoint of spin-delocalized topochemistry. Characterized in terms of the total and atomically partitioned number of effectively unpaired electrons as well as of the distribution of the latter over carbon atoms and described by selectively determined barriers of different reactions exhibiting topological essence of intermolecular interaction, sp2 nanocarbons reveal a peculiar topokinetics that lays the foundation of the stability of their radical properties.

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Section: Spin Nature Of the Reaction Final Productsmentioning

confidence: 99%

Section: Spin Nature Of the Reaction Final Productsmentioning

confidence: 99%

sp2 Carbon Stable Radicals

Sheka

2021

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“…The graphene edges can also be testified by the Raman spectra in Figure 1 b. Since the D peak (~1350 cm −1 ) requires a defect for its activation and the G peak (1580 cm −1 ) corresponds to the doubly degenerate zone center E 2g mode, we can see that, the longer the growth time of GNWs used, the larger the intensity ratio of the D to G (I D /I G ), which means more graphene edge defects and a higher degree of disorder shaped [ 30 , 31 ]. However, from the increasing intensity of the D peak and the increasing full width at half maximum (FWHM) of the 2D peak, it could be inferred that a longer growth time leads graphene nanosheets to nanocrystalline graphite.…”

Section: Resultsmentioning

confidence: 99%

Lateral Structured Phototransistor Based on Mesoscopic Graphene/Perovskite Heterojunctions

Zhou

Zhu

et al. 2021

Nanomaterials

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Due to their outstanding optical properties and superior charge carrier mobilities, organometal halide perovskites have been widely investigated in photodetection and solar cell areas. In perovskites photodetection devices, their high optical absorption and excellent quantum efficiency contribute to the responsivity, even the specific detectivity. In this work, we developed a lateral phototransistor based on mesoscopic graphene/perovskite heterojunctions. Graphene nanowall shows a porous structure, and the spaces between graphene nanowall are much appropriated for perovskite crystalline to mount in. Hot carriers are excited in perovskite, which is followed by the holes’ transfer to the graphene layer through the interfacial efficiently. Therefore, graphene plays the role of holes’ collecting material and carriers’ transporting channel. This charge transfer process is also verified by the luminescence spectra. We used the hybrid film to build phototransistor, which performed a high responsivity and specific detectivity of 2.0 × 103 A/W and 7.2*1010 Jones, respectively. To understand the photoconductive mechanism, the perovskite’s passivation and the graphene photogating effect are proposed to contribute to the device’s performance. This study provides new routes for the application of perovskite film in photodetection.

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“…The lower I D /I G value indicates that ACs exhibit more perfect and orderly graphite structures with a high graphitisation degree [52][53][54], while a higher I D /I G peak intensity ratio reveals more structural defects in carbon materials. Moreover, I D /I G values also serve to identify the size of the sp 2 domain, related to graphene structure, in the AC structure [53,55]. Figure 5 shows that AC6 (700 °C, 2 h, 2) had the highest graphitisation degree, followed by AC14 (700 °C, 1 h, 1.5)-presenting I D /I G values of 0.85 and 0.88, respectively.…”

Section: Raman Spectroscopymentioning

confidence: 99%

Application of design of experiments (DoE) for optimised production of micro- and mesoporous Norway spruce bark activated carbons

Reis

Larsson

Mathieu

et al. 2021

Biomass Conv. Bioref.

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In this work, Norway spruce (Picea abies (Karst) L.) bark was employed as a precursor to prepare activated carbon using zinc chloride (ZnCl2) as a chemical activator. The purpose of this study was to determine optimal activated carbon (AC) preparation variables by the response surface methodology using a Box–Behnken design (BBD) to obtain AC with high specific surface area (SBET), mesopore surface area (SMESO), and micropore surface area (SMICR). Variables and levels used in the design were pyrolysis temperature (700, 800, and 900 °C), holding time (1, 2, and 3 h), and bark/ZnCl2 impregnation ratio (1, 1.5, and 2). The optimal conditions for achieving the highest SBET were as follows: a pyrolysis temperature of 700 °C, a holding time of 1 h, and a spruce bark/ZnCl2 ratio of 1.5, which yielded an SBET value of 1374 m2 g−1. For maximised mesopore area, the optimal condition was at a pyrolysis temperature of 700 °C, a holding time of 2 h, and a bark/ZnCl2 ratio of 2, which yielded a SMESO area of 1311 m2 g−1, where mesopores (SMESO%) comprised 97.4% of total SBET. Correspondingly, for micropore formation, the highest micropore area was found at a pyrolysis temperature of 800 °C, a holding time of 3 h, and a bark/ZnCl2 ratio of 2, corresponding to 1117 m2 g−1, with 94.3% of the total SBET consisting of micropores (SMICRO%). The bark/ZnCl2 ratio and pyrolysis temperature had the strongest impact on the SBET, while the interaction between temperature and bark/ZnCl2 ratio was the most significant factor for SMESO. For the SMICRO, holding time was the most important factor. In general, the spruce bark AC showed predominantly mesoporous structures. All activated carbons had high carbon and low ash contents. Chemical characterisation indicated that the ACs presented disordered carbon structures with oxygen functional groups on the ACs’ surfaces. Well-developed porosity and a large surface area combined with favourable chemical composition render the activated carbons from Norway spruce bark with interesting physicochemical properties. The ACs were successfully tested to adsorb sodium diclofenac from aqueous solutions showing to be attractive products to use as adsorbents to tackle polluted waters. Graphical abstract

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Graphene Domain Signature of Raman Spectra of sp2 Amorphous Carbons

Cited by 56 publications

References 88 publications

sp2 Carbon Stable Radicals

sp2 Carbon Stable Radicals

Lateral Structured Phototransistor Based on Mesoscopic Graphene/Perovskite Heterojunctions

Application of design of experiments (DoE) for optimised production of micro- and mesoporous Norway spruce bark activated carbons

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