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Sains Malaysiana 48(6)(2019): 1187–1194
http://dx.doi.org/10.17576/jsm-2019-4806-05
Effect of Reaction Time
and Catalyst Feed Rate towards Carbon Nanotubes Yields and Purity by Using
Rotary Reactor
(Kesan Tindak Balas
Masa dan Kadar Suapan Pemangkin ke Arah Hasil dan Ketulenan Karbon Nanotiub
dengan Menggunakan Reaktor Putar)
RABITA FIRDAUS, NUR SYAHIDAH AFANDI, MEHRNOUSH KHAVARIAN
& ABDUL RAHMAN MOHAMED*
School
of Chemical Engineering, Universiti Sains Malaysia, 14300 NIibong Tebal, Pulau
Pinang, Malaysia
Received:
13 August 2018/Accepted: 3 December 2018
ABSTRACT
Continuous production
of multi-walled carbon nanotubes (MWCNTs) by chemical vapor
deposition (CVD) method was investigated in a rotary reactor. The aim
of the study was to investigate the effect of catalyst feeding rate and
reaction time on the MWCNTs production yield and purity.
Bimetallic Co-Mo supported on MgO was used for the growth of MWCNTs
and methane gas was used as the carbon precursor. The results indicated that
the highest yield of MWCNTs production was attained at the
reaction time of 180 min and catalyst feeding rate of 100 mg/min; this sample
also had the highest purity (99.16%). SEM and TEM analyses
of the synthesized product confirmed that most of the MWCNTs
were sinuous and entangled with a uniform diameter. Raman spectroscopy
indicated that the as-produced MWCNTs were mostly graphitic
with few disordered carbon and impurities. The results highlighted that
synthesized MWCNTs were highly pure which eliminates the need for MWCNTs
purification process.
Keywords: Carbon
nanotubes; catalyst feed rate; chemical vapor deposition (CVD);
reaction time
ABSTRAK
Pengeluaran tiub nano
karbon berbilang dinding (MWCNTs) secara berterusan melalui
proses penguraian wap bermangkin (CVD) telah dijalankan dalam
sebuah reaktor berputar. Tujuan kajian ini adalah untuk mengkaji kesan kadar
kemasukan pemangkin dan kadar masa reaksi terhadap hasil pengeluaran MWCNTs
dan ketulenan. Gabungan dwi logam Co-Mo tersokong di atas MgO telah digunakan
untuk pertumbuhan MWCNTs dan gas metana digunakan
sebagai prekursor karbon. Keputusan menunjukkan bahawa pengeluaran tertinggi
pengeluaran MWCNTs dicapai pada kadar masa reaksi 180 min dan kadar
kemasukan pemangkin 100 mg/min; sampel ini juga berketulenan tinggi (99.16%).
Analisis SEM dan TEM terhadap produk yang
disintesis itu mengesahkan bahawa kebanyakan MWCNTs
adalah bergabung dan terikat dengan diameter seragam. Spektroskopi Raman
menunjukkan bahawa MWCNTs yang dihasilkan kebanyakannya
adalah grafit dengan sedikit karbon dan bendasing. Keputusan menunjukkan bahawa MWCNTs
yang disintesis adalah sangat tulen dan tidak memerlukan proses penulenan MWCNTs.
Kata kunci: Kadar kemasukan pemangkin; kadar masa reaksi; karbon
nanotiub; penguraian wap bermangkin
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*Corresponding author; email: chrahman@usm.my
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