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Effect of hydrogen accumulation on the surface of Ni-containing nanodiamond catalysts

Evgeniya Alexandrovna Tveritinova 1
Evgeniya Alexandrovna Tveritinova
Yurii Nikolaevich Zhitnev 1
Yurii Nikolaevich Zhitnev
Inna Ivanovna Kulakova 1
Inna Ivanovna Kulakova
Nikolai Borisovich Cherkasov 1
Nikolai Borisovich Cherkasov
Serguei Vyacheslavovich Savilov 1
Serguei Vyacheslavovich Savilov
Valery Vasil'evich Lunin 1
Valery Vasil'evich Lunin
10.1016/j.mencom.2013.09.002
Published 2013-09-10
CommunicationVolume 23, Issue 5, 249-250
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Tveritinova E. A. et al. Effect of hydrogen accumulation on the surface of Ni-containing nanodiamond catalysts // Mendeleev Communications. 2013. Vol. 23. No. 5. pp. 249-250.
GOST all authors (up to 50) Copy
Tveritinova E. A., Zhitnev Y. N., Kulakova I. I., Kharlanov A. N., Cherkasov N. B., Savilov S. V., Lunin V. V. Effect of hydrogen accumulation on the surface of Ni-containing nanodiamond catalysts // Mendeleev Communications. 2013. Vol. 23. No. 5. pp. 249-250.
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TY - JOUR
DO - 10.1016/j.mencom.2013.09.002
UR - https://mendcomm.colab.ws/publications/10.1016/j.mencom.2013.09.002
TI - Effect of hydrogen accumulation on the surface of Ni-containing nanodiamond catalysts
T2 - Mendeleev Communications
AU - Tveritinova, Evgeniya Alexandrovna
AU - Zhitnev, Yurii Nikolaevich
AU - Kulakova, Inna Ivanovna
AU - Kharlanov, Andrey Nikolaevich
AU - Cherkasov, Nikolai Borisovich
AU - Savilov, Serguei Vyacheslavovich
AU - Lunin, Valery Vasil'evich
PY - 2013
DA - 2013/09/10
PB - Mendeleev Communications
SP - 249-250
IS - 5
VL - 23
ER -
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@article{2013_Tveritinova,
author = {Evgeniya Alexandrovna Tveritinova and Yurii Nikolaevich Zhitnev and Inna Ivanovna Kulakova and Andrey Nikolaevich Kharlanov and Nikolai Borisovich Cherkasov and Serguei Vyacheslavovich Savilov and Valery Vasil'evich Lunin},
title = {Effect of hydrogen accumulation on the surface of Ni-containing nanodiamond catalysts},
journal = {Mendeleev Communications},
year = {2013},
volume = {23},
publisher = {Mendeleev Communications},
month = {Sep},
url = {https://mendcomm.colab.ws/publications/10.1016/j.mencom.2013.09.002},
number = {5},
pages = {249--250},
doi = {10.1016/j.mencom.2013.09.002}
}
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Tveritinova, Evgeniya Alexandrovna, et al. “Effect of hydrogen accumulation on the surface of Ni-containing nanodiamond catalysts.” Mendeleev Communications, vol. 23, no. 5, Sep. 2013, pp. 249-250. https://mendcomm.colab.ws/publications/10.1016/j.mencom.2013.09.002.

Abstract

The effect of active hydrogen accumulation on the surface of the Ni-nanodiamond catalysts has been demonstrated. Lower bound estimation of the hydrogen capacity is 1.3 wt%. Oxygen-containing functional groups on the nanodiamond surface are presumably responsible for the hydrogen accumulation.

References

1.
Hydrogen storage by carbon materials
Ströbel R., Garche J., Moseley P.T., Jörissen L., Wolf G.
Journal of Power Sources, 2006
2.
Advanced composites storage containment for hydrogen
YOUNG K.
International Journal of Hydrogen Energy, 1992
3.
Nanoscale carbon material porosity effect on gas adsorption
Beyaz S., Lamari F.D., Weinberger B., Langlois P.
International Journal of Hydrogen Energy, 2010
4.
Investigation of hydrogen storage capacity of various carbon materials
XU W., TAKAHASHI K., MATSUO Y., HATTORI Y., KUMAGAI M., ISHIYAMA S., KANEKO K., IIJIMA S.
International Journal of Hydrogen Energy, 2007
5.
Graphene-based and graphene-like materials
Ivanovskii A.L.
Russian Chemical Reviews, 2012
6.
Carbon nanotubes in new materials
Rakov E.G.
Russian Chemical Reviews, 2013
7.
Spillover in Heterogeneous Catalysis
Conner W.C., Falconer J.L.
Chemical Reviews, 1995
8.
Effect of surface acidity of activated carbon on hydrogen storage
Agarwal R.K., Noh J.S., Schwarz J.A., Davini P.
Carbon, 1987
9.
Low-Temperature Generation of Basic Carbon Surfaces by Hydrogen Spillover
Menéndez J.A., Radovic L.R., Xia B., Phillips J.
The Journal of Physical Chemistry, 1996
10.
Improving hydrogen storage in Ni-doped carbon nanospheres
Zubizarreta L., Menéndez J.A., Pis J.J., Arenillas A.
International Journal of Hydrogen Energy, 2009
11.
Ni-doped carbon xerogels for H2 storage
Zubizarreta L., Menéndez J.A., Job N., Marco-Lozar J.P., Pirard J.P., Pis J.J., Linares-Solano A., Cazorla-Amorós D., Arenillas A.
Carbon, 2010
12.
A study on the hydrogen storage capacity of Ni-plated porous carbon nanofibers
Kim B., Lee Y., Park S.
International Journal of Hydrogen Energy, 2008
14.
Hydrogen storage in nickel catalysts supported on activated carbon
ZIELINSKI M., WOJCIESZAK R., MONTEVERDI S., MERCY M., BETTAHAR M.
International Journal of Hydrogen Energy, 2007
15.
Landau M.V., Savilov S.V., Kirikova M.N., Cherkasov N.B., Ivanov A.S., Lunin V.V., Koltypin Y., Gedanken A.
Mendeleev Communications, 2011
16.
Nanosized Nickel(or Cobalt)/Graphite Composites for Hydrogen Storage
Zhong Z.Y., Xiong Z.T., Sun L.F., Luo J.Z., Chen P., Wu X., Lin J., Tan K.L.
Journal of Physical Chemistry B, 2002
17.
Conversion of C2-C4 alcohols over copper-containing catalysts on carbon and fluorocarbon fibers
Tveritinova E.A., Zhitnev Y.N., Roshchina T.M., Lunin V.V.
Russian Journal of Physical Chemistry A, 2011
18.
Catalytic properties of a copper-carbon system formed by explosive decomposition of copper acetylide
Zhitnev Y.N., Tveritinova E.A., Lunin V.V.
Russian Journal of Physical Chemistry A, 2008