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Synthesis of nitrogen doped segmented carbon nanofibers via metal dusting of Ni-Pd alloy. / Mishakov, Ilya V.; Bauman, Yury I.; Shubin, Yury V. et al.

In: Catalysis Today, Vol. 388-389, 01.04.2022, p. 312-322.

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Mishakov IV, Bauman YI, Shubin YV, Kibis LS, Gerasimov EY, Mel'gunov MS et al. Synthesis of nitrogen doped segmented carbon nanofibers via metal dusting of Ni-Pd alloy. Catalysis Today. 2022 Apr 1;388-389:312-322. doi: 10.1016/j.cattod.2020.06.024

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Mishakov, Ilya V. ; Bauman, Yury I. ; Shubin, Yury V. et al. / Synthesis of nitrogen doped segmented carbon nanofibers via metal dusting of Ni-Pd alloy. In: Catalysis Today. 2022 ; Vol. 388-389. pp. 312-322.

BibTeX

@article{805bfb1665fe48f28d7a0da7947e2f56,
title = "Synthesis of nitrogen doped segmented carbon nanofibers via metal dusting of Ni-Pd alloy",
abstract = "A single-phase micro-disperse Ni-Pd (5 wt.%) alloy prepared by coprecipitation technique was studied as a catalyst precursor for the synthesis of the nanostructured carbon product. Catalytic synthesis of N-doped carbon nanofibers was implemented by the joint decomposition of C2H4Cl2 and CH3CN vapors in H2 excess at 600 °C. The in situ kinetic experiments performed in a flow gravimetric setup with McBain balances showed that the carbon deposition process is characterized by an induction period (18−20 min). The intensive metal dusting of the Ni-Pd alloyed precursor in reaction conditions was found to lead to its complete disintegration. The obtained submicron-sized Ni-Pd particles were shown by XRD to have the same composition as the starting Ni-Pd (5%) precursor. The growth of carbon filaments accompanied the rapid disintegration of Ni-Pd alloy. The addition of acetonitrile vapors into the reaction mixture was found to enhance carbon yield from 24 (0%) to 40.5 (5 vol.%) and 50.9 (8 vol.%) grams per 1 g of catalyst for 2 h of reaction. Joint catalytic processing of C2H4Cl2 and CH3CN was shown to be sufficient for the production of carbon nanofibers doped with nitrogen. According to XPS and EDX data, the average amount of nitrogen within the obtained N-CNF was about 1.8 wt.%. It was revealed by microscopic studies (SEM, TEM) that the produced N-doped carbon filaments are characterized with a rather regular segmental structure similar to that observed for a reference sample of N-free CNF. The synthesized N-CNF samples are characterized by ID/IG ∼ 1.3 (Raman spectroscopy) and high textural parameters (SBET ∼ 390−450 m2/g, Vpore ∼ 0.6 cm3/g).",
keywords = "1,2-dichloroethane, Acetonitrile, Metal dusting, N-doped carbon nanofibers, Nickel–palladium alloy, Self-organizing catalyst",
author = "Mishakov, {Ilya V.} and Bauman, {Yury I.} and Shubin, {Yury V.} and Kibis, {Lidiya S.} and Gerasimov, {Evgeny Yu} and Mel'gunov, {Maksim S.} and Stoyanovskii, {Vladimir O.} and Korenev, {Sergey V.} and Vedyagin, {Aleksey A.}",
note = "The authors are grateful to the Tomsk Polytechnic University Target Program {\textquoteleft}Science{\textquoteright}, project FSWW-2020-0011. Characterization of the samples was performed using the equipment of the Center of Collective Use {\textquoteleft}National Center of Catalysts Research{\textquoteright}. The authors are grateful to Alexandra N. Serkova for the performed SEM studies. The present research was financially supported by the Russian Foundation of Basic Research (project No. 18-29-19053_mk). ",
year = "2022",
month = apr,
day = "1",
doi = "10.1016/j.cattod.2020.06.024",
language = "English",
volume = "388-389",
pages = "312--322",
journal = "Catalysis Today",
issn = "0920-5861",
publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - Synthesis of nitrogen doped segmented carbon nanofibers via metal dusting of Ni-Pd alloy

AU - Mishakov, Ilya V.

AU - Bauman, Yury I.

AU - Shubin, Yury V.

AU - Kibis, Lidiya S.

AU - Gerasimov, Evgeny Yu

AU - Mel'gunov, Maksim S.

AU - Stoyanovskii, Vladimir O.

AU - Korenev, Sergey V.

AU - Vedyagin, Aleksey A.

N1 - The authors are grateful to the Tomsk Polytechnic University Target Program ‘Science’, project FSWW-2020-0011. Characterization of the samples was performed using the equipment of the Center of Collective Use ‘National Center of Catalysts Research’. The authors are grateful to Alexandra N. Serkova for the performed SEM studies. The present research was financially supported by the Russian Foundation of Basic Research (project No. 18-29-19053_mk).

PY - 2022/4/1

Y1 - 2022/4/1

N2 - A single-phase micro-disperse Ni-Pd (5 wt.%) alloy prepared by coprecipitation technique was studied as a catalyst precursor for the synthesis of the nanostructured carbon product. Catalytic synthesis of N-doped carbon nanofibers was implemented by the joint decomposition of C2H4Cl2 and CH3CN vapors in H2 excess at 600 °C. The in situ kinetic experiments performed in a flow gravimetric setup with McBain balances showed that the carbon deposition process is characterized by an induction period (18−20 min). The intensive metal dusting of the Ni-Pd alloyed precursor in reaction conditions was found to lead to its complete disintegration. The obtained submicron-sized Ni-Pd particles were shown by XRD to have the same composition as the starting Ni-Pd (5%) precursor. The growth of carbon filaments accompanied the rapid disintegration of Ni-Pd alloy. The addition of acetonitrile vapors into the reaction mixture was found to enhance carbon yield from 24 (0%) to 40.5 (5 vol.%) and 50.9 (8 vol.%) grams per 1 g of catalyst for 2 h of reaction. Joint catalytic processing of C2H4Cl2 and CH3CN was shown to be sufficient for the production of carbon nanofibers doped with nitrogen. According to XPS and EDX data, the average amount of nitrogen within the obtained N-CNF was about 1.8 wt.%. It was revealed by microscopic studies (SEM, TEM) that the produced N-doped carbon filaments are characterized with a rather regular segmental structure similar to that observed for a reference sample of N-free CNF. The synthesized N-CNF samples are characterized by ID/IG ∼ 1.3 (Raman spectroscopy) and high textural parameters (SBET ∼ 390−450 m2/g, Vpore ∼ 0.6 cm3/g).

AB - A single-phase micro-disperse Ni-Pd (5 wt.%) alloy prepared by coprecipitation technique was studied as a catalyst precursor for the synthesis of the nanostructured carbon product. Catalytic synthesis of N-doped carbon nanofibers was implemented by the joint decomposition of C2H4Cl2 and CH3CN vapors in H2 excess at 600 °C. The in situ kinetic experiments performed in a flow gravimetric setup with McBain balances showed that the carbon deposition process is characterized by an induction period (18−20 min). The intensive metal dusting of the Ni-Pd alloyed precursor in reaction conditions was found to lead to its complete disintegration. The obtained submicron-sized Ni-Pd particles were shown by XRD to have the same composition as the starting Ni-Pd (5%) precursor. The growth of carbon filaments accompanied the rapid disintegration of Ni-Pd alloy. The addition of acetonitrile vapors into the reaction mixture was found to enhance carbon yield from 24 (0%) to 40.5 (5 vol.%) and 50.9 (8 vol.%) grams per 1 g of catalyst for 2 h of reaction. Joint catalytic processing of C2H4Cl2 and CH3CN was shown to be sufficient for the production of carbon nanofibers doped with nitrogen. According to XPS and EDX data, the average amount of nitrogen within the obtained N-CNF was about 1.8 wt.%. It was revealed by microscopic studies (SEM, TEM) that the produced N-doped carbon filaments are characterized with a rather regular segmental structure similar to that observed for a reference sample of N-free CNF. The synthesized N-CNF samples are characterized by ID/IG ∼ 1.3 (Raman spectroscopy) and high textural parameters (SBET ∼ 390−450 m2/g, Vpore ∼ 0.6 cm3/g).

KW - 1,2-dichloroethane

KW - Acetonitrile

KW - Metal dusting

KW - N-doped carbon nanofibers

KW - Nickel–palladium alloy

KW - Self-organizing catalyst

UR - http://www.scopus.com/inward/record.url?scp=85086942326&partnerID=8YFLogxK

U2 - 10.1016/j.cattod.2020.06.024

DO - 10.1016/j.cattod.2020.06.024

M3 - Article

AN - SCOPUS:85086942326

VL - 388-389

SP - 312

EP - 322

JO - Catalysis Today

JF - Catalysis Today

SN - 0920-5861

ER -

ID: 24615597