Utilizing embedded ultra-small Pt nanoparticles as charge trapping layer in flashristor memory cells
Tarih
2019Yazar
Orak, Ikram and Eren, Hamit and Biyikli, Necmi and Dana, Aykutlu
Üst veri
Tüm öğe kaydını gösterÖzet
In this study, a methodology for producing highly controlled and
uniformly dispersed metal nanoparticles were developed by atomic layer
deposition (ALD) technique. All-ALD grown thin film flash memory (TFFM)
cells and their applications were demonstrated with ultra-small platinum
nanoparticles (Pt-NPs) as charge trapping layer and control tunnel oxide
layer. The ultra-small Pt-NPs possessed sizes ranging from 2.3 to 2.6 nm
and particle densities of about 2.5 x 10(13) cm(-b). The effect of
Pt-NPs embedded on the storage layer for charging was investigated. The
charging effect of ultra-small Pt-NPs the storage layer was observed
using the electrical characteristics of TFFM. The Pt-NPs were observed
by a high-resolution scanning electron microscopy (HR-SEM). The memory
effect was manifested by hysteresis in the I-DS-V-DS and I-Ds-V-GS
curves. The charge storage capacity of the TFFM cells demonstrated that
ALD-grown Pt-NPs in conjunction with ZnO layer can be considered as a
promising candidate for memory devices. Moreover, ZnO TFFM showed a
I-ON/I-OFF ratio of up to 52 orders of magnitude and its threshold
voltage (V-th) was approximately -4.1 V using I-ds (-a/b) - V-gs curve.
Fabricated TFFMs exhibited clear pinch-off and show n-type field effect
transistor (FET) behavior. The role of atomic-scale controlled Pt-NPs
for improvement of devices were also discussed and they indicated that
ALD-grown Pt-NPs can be utilized in nanoscale electronic devices as
alternative quantum dot structures.
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