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Sains Malaysiana 48(6)(2019): 1233–1238 http://dx.doi.org/10.17576/jsm-2019-4806-10
Synthesis of Graphene/Cu2O Thin Film Photoelectrode
via Facile Hydrothermal Method for Photoelectrochemical
Measurement (Sintesis Fotoelektrod Filem Nipis Grafen/Cu2O
melalui Kaedah
Hidroterma Tindak Balas Mudah bagi
Pengukuran Fotoelektrokimia) ROSMAHANI MOHD
SHAH1,
ROZAN
MOHAMAD
YUNUS2*,
MOHD
SHAHBUDIN
MASDAR@MASTAR1,2,
LORNA
JEFFEREY
MINGGU2,
WONG
WAI
YIN2
& ABDUL AMIR H. KADHUM1 1Research Centre for Sustainable
Process Technology, Faculty of Engineering & Built Environment,
Universiti Kebangsaan Malaysia, 43600 UKM Bangi, Selangor
Darul Ehsan, Malaysia 2Fuel Cell Institute, Universiti Kebangsaan Malaysia, 43600 UKM Bangi, Selangor
Darul Ehsan, Malaysia Diserahkan: 21 November 2018/Diterima:
1 Mac 2019 ABSTRACT The process of carbon dioxide
(CO2) reduction by using efficient
non-precious-metal catalyst to make the process be economical has
brought a comprehensive research in the area. In this study, graphene
layer in copper foil was easily synthesized using hydrothermal method
at temperature 200°C in 3 h duration. Diffraction peaks in XRD at around 29°, 36°, 42° and
74° in the composites correlate to the (110), (111), (200) and (311)
crystalline planes of cubic cuprous oxide (Cu2O),
while peak at 27° showed the carbon graphitic peak. Raman confirms
the presence of the graphene layer on Cu2O. Photoelectrochemical
performance test of Graphene/Cu2O demonstrated that the
photoelectrocatalyst showing the photocurrent density 9.6
mA cm-2 at -0.8V vs Ag/AgCl. This study
demonstrated a potential of semiconductor-based hybrid electrode
for an efficient photoelectrocatalytic
of CO2 reduction. Keywords:
CO2 reduction; cuprous oxide; graphene;
photoelectrochemical ABSTRAK Proses penurunan
karbon dioksida
(CO2)
dengan menggunakan
pemangkin bukan logam berharga yang berkesan untuk menghasilkan proses yang lebih berekonomi telah membawa kepada penyelidikan yang komprehensif dalam bidang tersebut.
Dalam
kajian ini, lapisan
grafen pada
kerajang tembaga disintesis dengan mudah menggunakan kaedah hidroterma pada suhu 200°C dalam tempoh masa 3 jam.
Puncak belauan XRD pada sudut 29°, 36°, 42° dan 74° menunjukkan satah hablur kubik
oksida (Cu2O) (110), (111), (200)
dan (311) dan puncak
grafit karbon
ditunjukkan pada sudut 27°. Raman mengesahkan
kehadiran lapisan
grafen pada Cu2O.
Ujian
prestasi fotopemangkinan grafen/Cu2O menunjukkan
bahawa fotomangkin
tersebut mempunyai ketumpatan fotokimia 9.6 mA cm-2
pada -0.8V vs Ag/AgCl. Kajian ini menyumbang kepada penghasilan elektrod hibrid berasaskan semikonduktor sebagai fotomangkin yang berkesan untuk penurunan CO2. Kata kunci: Fotoelektrokimia;
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*Pengarang untuk surat-menyurat; email: rozanyunus@ukm.edu.my
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