Evolution of glassy carbon under heat treatment: correlation structure–mechanical properties

Jurkiewicz, Karolina; Pawlyta, Mirosława; Zygadło, Dorota; Chrobak, D.; Düber, S.; Wrzalik, R.; Ratuszna, A.; Burian, A.

doi:10.1007/s10853-017-1753-7

Cited by 116 publications

(92 citation statements)

References 67 publications

(85 reference statements)

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“…Extrapolation of the hardness fit to zero and 100% free carbon leads to values of 12.1 and 6 GPa, respectively. While the estimated value for the SiOC glass without free carbon (12.1 GPa) is slightly above the typical values reported in the literature (∼10 GPa), the hardness of the free carbon phase matched closely with the reported values ( H = 5.5‐6.0 GPa).…”

Section: Resultssupporting

confidence: 88%

“…By extrapolating the linear fit to zero percent of free carbon, the Young's modulus of the “pure” SiC x O 2(1− x ) x = ∼0.4‐0.5 is found to be ∼117 GPa, in good agreement with the Young's modulus values measured on SiOC glasses with negligible amount of free carbon and x = 0.37 . The same fit extrapolated to 100% free carbon estimates an elastic modulus value of the free carbon phase ∼63 GPa which is higher than the value reported for carbon materials derived from pyrolysis of organic resins, which is ∼40 GPa . The lower elastic modulus that the high‐C samples display compared with the low‐C ones could help in rationalizing the experimental evidence of the lower tendency to crack during pyrolysis shown by the high‐C samples.…”

Section: Resultssupporting

confidence: 76%

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Influence of free carbon on the Young's modulus and hardness of polymer‐derived silicon oxycarbide glasses

et al. 2018

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Silicon oxycarbide (SiOC) glasses in the form of thin, dense, and crack‐free samples were fabricated according to the polymer pyrolysis route starting from cross‐linked polysiloxane. The amount of free carbon in the final SiOC materials was varied in the range 18‐60 vol%. The mechanical properties of the SiOC glasses were measured by nanoindentaion technique and revealed that both the Young's modulus and the hardness decrease with increase in the free carbon content and follow a simple rule of mixtures model.

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Section: Resultssupporting

confidence: 88%

Section: Resultssupporting

confidence: 76%

Influence of free carbon on the Young's modulus and hardness of polymer‐derived silicon oxycarbide glasses

et al. 2018

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“…This is in agreement with the outcome of work published by Guo et al [92] showing ADF STEM images of agglomerated defective sites in the glassy carbon structure. The proposed models were confirmed by direct HRTEM observations for the same series of polyfurfuryl-alcohol based glassy carbons published in Reference [93]. Examples of the microscopic images for glassy carbons pyrolysed at 800 • C, 1500 • C, and 2500 • C are confronted with the structural models in Figure 26.…”

Section: Glass-like Carbon and Other Pyrolysed Non-graphitising Carbonssupporting

confidence: 66%

Structure of Carbon Materials Explored by Local Transmission Electron Microscopy and Global Powder Diffraction Probes

Jurkiewicz

Pawlyta

Burian

2018

Self Cite

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Transmission electron microscopy and neutron or X-ray diffraction are powerful techniques available today for characterization of the structure of various carbon materials at nano and atomic levels. They provide complementary information but each one has advantages and limitations. Powder X-ray or neutron diffraction measurements provide structural information representative for the whole volume of a material under probe but features of singular nano-objects cannot be identified. Transmission electron microscopy, in turn, is able to probe single nanoscale objects. In this review, it is demonstrated how transmission electron microscopy and powder X-ray and neutron diffraction methods complement each other by providing consistent structural models for different types of carbons such as carbon blacks, glass-like carbons, graphene, nanotubes, nanodiamonds, and nanoonions.

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“…Resins are important compounds in the production of many carbon materials, e.g., as binder matrix for carbon fiber-reinforced carbon materials (CFRC), a light-weight material with excellent mechanical properties even at high temperatures. Upon heat treatment, the PF resin is gradually transformed into a non-graphitizing glassy carbon [49,50] consisting of highly cross-linked graphene stacks, which once were thought to be ribbon-like, but are now acknowledged as being of made of highly curved graphene sheets with a high content of fullerene-like structures [51][52][53][54]. Key properties of glassy carbon materials, such as thermal conductivity, chemical resistance, hardness, density, and coefficient of thermal expansion are closely related to the carbon microstructure and the porosity.…”

Section: Introductionmentioning

confidence: 99%

An advanced structural characterization of templated meso-macroporous carbon monoliths by small- and wide-angle scattering techniques

Badaczewski¹,

Loeh²,

Pfaff³

et al. 2020

Beilstein J. Nanotechnol.

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This study is dedicated to link the nanoscale pore space of carbon materials, prepared by hard-templating of meso-macroporous SiO 2 monoliths, to the corresponding nanoscale polyaromatic microstructure using two different carbon precursors wthat generally exhibit markedly different carbonization properties, i.e., a graphitizable pitch and a non-graphitizable resin. The micro-and mesoporosity of these monolithic carbon materials was studied by the sorption behavior of a relatively large organic molecule (p-xylene) in comparison to typical gas adsorbates (Ar). In addition, to obtain a detailed view on the nanopore space small-angle neutron scattering (SANS) combined with in situ physisorption was applied, using deuterated p-xylene (DPX) as a contrast-matching agent in the neutron scattering process. The impact of the carbon precursor on the structural order on an atomic scale in terms of size and disorder of the carbon microstructure, on the nanopore structure, and on the template process is analyzed by special evaluation approaches for SANS and wide-angle X-ray scattering (WAXS). The WAXS analysis shows that the pitch-based monolithic material exhibits a more ordered microstructure consisting of larger graphene stacks and similar graphene layer sizes compared to the monolithic resin. Another major finding is the discrepancy in the accessible micro/mesoporosity between Ar and deuterated p-xylene that found for the two different carbon precursors, pitch and resin, which can be regarded as representative carbon precursors in general. These differences essentially indicate that physisorption using probe gases such as Ar or N 2 can provide misleading parameters if to be used to appraise the accessibility of the nanoscale pore space.

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Evolution of glassy carbon under heat treatment: correlation structure–mechanical properties

Cited by 116 publications

References 67 publications

Influence of free carbon on the Young's modulus and hardness of polymer‐derived silicon oxycarbide glasses

Influence of free carbon on the Young's modulus and hardness of polymer‐derived silicon oxycarbide glasses

Structure of Carbon Materials Explored by Local Transmission Electron Microscopy and Global Powder Diffraction Probes

An advanced structural characterization of templated meso-macroporous carbon monoliths by small- and wide-angle scattering techniques

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