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Sains Malaysiana 48(8)(2019): 1745–1752
http://dx.doi.org/10.17576/jsm-2019-4808-21
Novel Surface-Enhanced
Raman Scattering Substrate based on Functionalized Silicon Nanowires
(Raman Permukaan-Dipertingkatkan
Sebaran Substrat Baru berasaskan Silikon Berfungsi Wayar Nano)
IRAM MAHMOOD1*, ISHAQ AHMAD2,3 & ISHFAQ AHMAD4
1Department
of Industrial Engineering, College of Engineering, King Khalid University Abha
61413, Kingdom of Saudi Arabia
2National
Center for Physics, Islamabad, 44000, Pakistan
3NPU-NCP
Joint International Research Center for Advanced Nanomaterials and
Defects Engineering, Northwestern Polytechnical University, Xi'an
710072, China
4Department
of Mathematics and Statistics, Faculty of Basic and Applied Sciences,
International Islamic University, Islamabad, Pakistan
Received: 11
February 2019/Accepted: 21 May 2019
ABSTRACT
This study reports synthesis
of a new Surface-Enhanced Raman Scattering (SERS)
substrate using Silicon nanowires (SiNW's) arrays, produced through
chemical etching, and functionalized by tailoring their surface
chemistry with nitrogen containing groups. From SEM characterization, phenomenon of micro
channel formation, porosity and amorphous nature for the as prepared
SiNWs was observed. Photoluminescence (PL) spectrum showed that these
nanowires have broad emission band in the range of 500-900 nm. Also,
change in the surface chemistry of Si nanowires after nitrogen treatment
was observed by elemental analysis, EDX and X-ray photoelectron spectroscopy.
The data showed that raising the modification temperature also increased
the nitrogen content. At high temperature, pyridine and aromatic
amines were the dominant functional groups while a small amount
of quaternary nitrogen and protonated amide were also present. Methylene
blue (MB)
was used as a probe molecule to investigate SERS activities
of functionalized SiNWs. The enhancement factor was estimated to
be 107-109.
Interaction of nitrogen containing groups on the surface of SiNWs
with MB molecules resulted in high adsorption of MB on the substrate and higher
signal detection by SERS.
Keywords: Methylene
blue; photoluminescence; Raman scattering; surface enhanced Raman scattering;
silicon nanowires
ABSTRAK
Kajian ini melaporkan
sintesis substrak Raman Permukaan-Dipertingkatkan Sebaran (SERS)
menggunakan susunan nanowayar silikon melalui proses punaran secara
kimia, serta penukaran sifat kimia permukaan dengan kumpulan berfungsi
bernitrogen. Melalui pencirian SEM, pembentukan saluran mikro, liang
dan ciri-ciri amorfous telah diperhatikan. Spektrum fotoluminesens
menunjukkan bahawa nanowayar yang terhasil mempunyai jalur pancaran
lebar dalam julat 500-900 nm. Di samping itu, perubahan kimia permukaan
nanowayar selepas rawatan nitrogen telah dikaji dengan analisis
unsur, EDX dan
spektroskopi fotoelektron sinar-X. Data yang diperoleh menunjukkan
bahawa ubahsuaian melalui suhu juga meningkatkan kandungan nitrogen.
Pada suhu tinggi, piridina dan amina aromatik adalah kumpulan berfungsi
utama dengan terdapat kandungan kecil nitrogen kuaternari dan amida
juga terbentuk. Metilena biru (MB)
telah digunakan sebagai molekul model untuk mengkaji aktiviti SERS bagi
substrak SiNWs yang terhasil. Faktor peningkatan sebanyak 107-109
telah diperoleh. Interaksi antara kumpulan berfungsi
nitrogen pada permukaan SiNWs dan molekul MB menyebabkan penjerapan MB yang
tinggi, lalu mencapai pengesanan isyarat SERS yang tinggi.
Kata kunci:
Fotoluminesens; metilena biru; serakan Raman; serakan Raman permukaan dipertingkatkan;
silikon nanowayar
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*Corresponding author; email: irahmad@kku.edu.sa
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