Sains Malaysiana
37(3): 289-293(2008)
Carbon Nanopipe Catalysed by As-Prepared NiO Nanoparticles
(Karbon Nanopaip Dimangkinkan oleh Nanozaral NiO Seperti Tersedia)
Noorhana Yahya
Electrical and Electronics Engineering Department
Universiti Teknologi PETRONAS, Bandar Seri Iskandar
31750, Tronoh, Perak, Malaysia
Samaila Bawa Waje & Irmawati Ramli
Advanced Materials and Nanotechnology Laboratory (AMNL)
Institute of Advanced Technology, Universiti Putra Malaysia
43400 UPM Serdang, Selangor
Darul Ehsan, Malaysia.
ABSTRACT
Carbon nanopipes catalyzed by high purity nickel oxide
(NiO) nanoparticles were reported. The nanocrystals catalysts were
first prepared using precipitation technique and characterized using
x-ray diffraction (XRD), energy dispersive x-ray (EDX) and scanning
electron microscopy (SEM) and subsequently used as catalyst for
the formation of nanotubes. Pure phase, rhombohedral nickel oxide
formation was identified from the XRD data, with the major peak
located at 43.29o of the 2θ degree corresponding
to a (202) plane. A pulsed laser ablation deposition technique (PLAD)
was used to produce the CNTs. From the SEM micrograph, deposited
CNTs shows a web-like structure, while the HR-TEM reveals carbon
nanopipes with a length of 10 micron and diameter of 430 nm, suggesting
that the nanocrystals aggregate and forms bigger cluster consequence
of the ablation process.
Keywords: Nickel
oxide; Rhombohedral; Precipitation; Pulsed Laser Ablation Deposition
ABSTRAK
Karbon nanopaip bermangkinkan partikal oksida nikel nanosaiz dan berketulenan tinggi dilaporkan.
Mangkin nanohablur ini telah disediakan dengan menggunakan kaedah
pemendakan dan telah menggunakan
teknik pembelauan Sinar-X (XRD), serakan tenaga sinar–X (EXD) dan
mikroskop elektron(SEM). Ia seterusnya telah digunakan sebagai mangkin
dalam pembentukan karbon tiub nano. Fasa tulen, pembentukan imbasan
oksida nikel rombohedral telah dikenalpasti daripada data sinar
–X yang diperoleh dengan puncak utama dilokasi 2θ = 43.29 yang diindeks kepada satah (202). Teknik
Dedenyut laser ablasi (PLAD) digunakan untuk menghasilkan karbon
tiub nano. Merujuk kepada grafmikro, karbon nanopaip yang termendak
menunjukkan struktur ala-jaringan manakala Mikroskop transmisi elektron
resolusi tinggi (HR-TEM) menunjukkan karbon nanopaip dengan panjang
10 mikron dan diameter 430 nm. Dicadangkan bahawa mangkin
nanohablur telah membentuk
kluster yang besar akibat daripada proses ablasi tersebut.
Kata kunci: Nikel oksida; rombohedron; pemendakan; pengenapan
ablasi dedenyut (PLAD)
REFERENCES/RUJUKAN
Ago, H., Komatsu, T., Ohshima, S., Kuriki, Y & Yumura,
M. 2000. Dispersion of metal nanoparticles for aligned carbon nanotubes arrays. Appl. Phys. Lett. 77: 77-81.
Chen, P., Wu, X., Sun, X., Lin, J., Li, W & Tan,
K.L. 1999. Electronic
Structure and Optical Limiting Behavior of Carbon Nanotubes, Phys. Rev. Lett. 82: 2548-2551.
Chow, G-M & Ivanova, N. 1998. Nanostructured Materials Science and Technology.
Kluwer Academic Publishers. Dordrecht.
Emmanuel, L., Philippe, S.,
Yolande, K & Philippe, K. 2006.
New efficient Fe2O3 and
FeMo supported OMCVD catalysts for single wall carbon nanotubes.
Growth. Cat. Comm 7(8):
604-609.
Hua-Qiang, W., Yun-Jie, C.,
Pin-Shi, Y., Hong-Yan, X & Xian-Wen, W 2005. Chem. Phy. Lett. 406(1-3): 148-153.
Marine, W., Partone, L., Luk’yanchuk, B & Sentis,
M. 2000. Strategy of nanocluster and nanostructure synthesis by
conventional pulsed laser ablation. Appl.
Surf. Sci. 154-155: 345-352.
Sinnott, S.B., Andrews, R., Qian, D., Rao, A.M., Mao,
Z and Dickey, E.C. 1999. Model
of carbon nanotube growth through chemical vapor deposition, Chem. Phys. Lett. 315: 25-30.
Tao, D & Wei, F. 2004. New procedure towards
size-homogeneous and well-dispersed nickel oxide nanoparticles of
30 nm. Mater.
Lett. 58: 3226-3228.
Xiang, L., Wei-Xiang, C., Jie, Z., Wei, X & Zhu-De,
X. 2005. Microwave Polyol
synthesis of Pt CNTs Catalysts: Effects of pH on particle size and
electro catalytic activity for methanol electrooxidal.
Carbon 43(10): 2168-2174.
Yahya, N., Beh, H.G & Hashim, M. 2005. Development of pulsed laser ablation deposition
system for the formation of web-like carbon nanotubes. American Journal of Applied Science 2(11):
1509-1515.
Yahya, N., Moh’d, H.M.S., Ismayadi, I., Beh, H. G., Moh’d,
S.E.S., Rakesh, B.D. and Ahmadun, N.Z.A. 2004. Carbon Nanotubes an overview, Magazine of Physics, Science and Ideas.
4. (1&2): 30-34.
Yoon, J., Ru, C.Q & Mioduchowski,
A. 2005. Vibration and instability of carbon nanotubes
conveying fluid, Composites Science and Technology 65 (9):
1326-1336.
Yudasaka, M., Kasuya, Y., Kokai, F., Takahashi, K., Takizawa,
M., Bandow, S & Iijima,
S. 2001. Causes of different catalytic activities of metals in formation
of single-wall carbon nanotubes. Appl.
Phys. A. 74:377-385.
Zhang, H., Ding, Y., Wu, C., Chen, Y., Zhu, Y., He, Y.,
& Zhong, S. 2003. Effects of laser power on the formation of carbon
nanotubes prepared in CO2 continuous wave laser ablation at room
temperature. Physica B: Cond.
Matt. 325: 224-229.
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