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Sains Malaysiana 45(8)(2016): 1213–1219
The
Effect of Al(NO3)3 Concentration
on the Formation of AuNPs using Low Temperature Hydrothermal Reaction for
Memory Application
(Kesan Kepekatan
Al(NO3)3 ke atas Pembentukan
AuNPs dengan Menggunakan Tindak Balas Hidroterma Suhu Rendah untuk
Aplikasi Ingatan)
S.A. NG1, K.A. RAZAK,1,2*, K.Y. CHEONG1, K.C. AW3
1School
of Materials and Mineral Resources Engineering, Universiti Sains Malaysia, 14300
Nibong Tebal, Pulau Pinang, Malaysia
2NanoBiotechnology
Research and Innovation, INFORMM, Universiti Sains Malaysia, 11800 Pulau Pinang,
Malaysia
3Mechanical
Engineering, The University of Auckland, Auckland, New Zealand
Received: 20 April 2015/Accepted: 18
November 2015
ABSTRACT
Distribution of gold nanoparticles (AuNPs) on a substrate becomes
crucial in nanotechnology applications. This work describes a route to
fabricate AuNPs directly on silicon substrates by using an aluminum template in
hydrothermal reaction at 80°C for 1 h. The effect of aluminum nitrate (Al(NO3)3)
concentration in the hydrothermal bath was investigated. The properties of
AuNPs were studied using field-emission scanning electron microscope (FESEM),
x-ray diffractometer (XRD) and semiconductor
characterization system (SCS). Two distinct sizes of AuNPs were
observed by FESEM. XRD analysis proved the
formation of AuNPs directly on the substrate. AuNPs were embedded between
polymethylsilsesquioxane (PMSSQ) in order to investigate their
effect on memory properties. The sample grown in 0.1 M Al(NO3)3 exhibited the largest hysteresis window (2.6 V) and the
lowest Vth (2.2 V) to turn ‘ON’
the memory device. This indicated that good distribution of FCC structure
AuNPs with 80±4 nm and 42±7 nm of large and small particles produced better
charge storage capability. Charge transport mechanisms of AuNPs embedded in PMSSQ were explained in details whereby electrons from Si are
transported across the barrier by thermionic effects via field-assisted
lowering at the Si-PMSSQ interface with the combination
of the Schottky and Poole Frenkel emission effect in Region 1. Trapped charge
limited current (TCLC) and space charge limited current
(SCLC)
transport mechanism occurred in Region 2 and Region 3.
Keywords: Gold nanoparticles; hydrothermal; memory devices;
template
ABSTRAK
Taburan nanopartikel emas (AuNPs) pada substrat adalah penting dalam
aplikasi nanoteknologi. Kajian ini menerangkan cara untuk menghasilkan
AuNPs secara langsung di atas substrat silikon dengan menggunakan
templat aluminium dalam tindak balas hidroterma pada suhu 80°C
selama 1 jam. Kesan kepekatan aluminium nitrat (Al(NO3)3) dalam
rendaman hidroterma dikaji. Sifat AuNPs telah dikaji menggunakan
pancaran medan mikroskop elektron imbasan (FESEM), pembelauan sinar-x
(XRD) dan sistem pencirian semikonduktor (SCS). Dua saiz berbeza
AuNPs diperhatikan menggunakan FESEM. Analisis XRD membuktikan pembentukan
AuNPs secara langsung ke atas substrat. AuNPs tertanam antara polimetilsilseskuioksana
(PMSSQ) untuk mengkaji kesannya ke atas sifat ingatan. Sampel yang
dihasilkan di dalam 0.1 M Al(NO3)3 menghasilkan tetingkap histeresis
terbesar (2.6 V) dan Vth (2.2 V) terendah untuk menghidupkan peranti
ingatan. Ini menunjukkan pengagihan yang baik oleh struktur FCC
AuNPs dengan 80±4 nm dan 42±7 nm partikel besar dan
kecil menghasilkan keupayaan penyimpanan cas yang lebih baik. Mekanisme
pengangkutan cas di dalam AuNPs tertanam dalam PMSSQ telah dijelaskan
secara terperinci manakala elektron daripada Si diangkut merentasi
halangan oleh kesan termionik melalui perendahan medan-berbantu
pada antara muka Si-PMSSQ dengan gabungan kesan pancaran Schottky
dan Poole Frenkel dalam Rantau 1. Mekanisme pengangkutan perangkap
arus cas terhad (TCLC) dan ruang arus cas terhad (SCLC) berlaku
di Rantau 2 dan 3.
Kata kunci: Hidroterma; nanopartikel emas;
peranti ingatan; templat
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*Corresponding author; email: khairunisak@usm.my
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