Analysis of Program Speed Characteristics Having Non-ideal Channel Profile in 3D NAND
Flash Memory
LeeJaewoo1
KimYungjun2
ShinYoocheol2
ParkSeongjo2
KangHojong2
KangDaewoong3,*
KangMyounggon1,*
-
(Department of Electronics Engineering, Korea National University of Transportation,
Chungju 380-702, Korea)
-
(Department of SK Hynix NAND PI, 2091 Gyeongchung-daero, Bubal-eup, Icheon-si, Gyeonggi-do,
Korea)
-
(Next Generation Semiconductor Convergence and Open Sharing System, Seoul National
University, Seoul 151-747, Korea)
Copyright © The Institute of Electronics and Information Engineers(IEIE)
Index Terms
3D NAND flash memory, channel profile, electric field, program speed, threshold voltage
I. INTRODUCTION
Since the initial commercial introduction of three-dimensional (3D) NAND Flash memory,
vertical NAND Flash memory production has experienced remarkable growth, firmly establishing
itself as the dominant data storage solution across a wide array of applications [1-4]. The emergence of 3D vertical NAND Flash memory has marked a pivotal development,
addressing the limited scalability of two-dimensional (2D) NAND Flash memory. Consequently,
the continuous stacking of 3D NAND Flash memory is poised to surpass 200 stacks in
the near future, revolutionizing data storage capabilities [5-9]. However, as the stacking height increases, the challenge of maintaining precise
control over channel hole dry etching intensifies. This has given rise to tapering
issues, characterized by differential etching at the top and bottom of the process,
posing a significant obstacle in achieving a perfectly circular profile during the
etching process. In light of these intricate challenges, it is imperative to underscore
the significance of program speed, which plays a pivotal role in optimizing the performance
and efficiency of 3D NAND Flash memories. The program speed dictates how rapidly data
can be written to memory cells and directly affects the overall efficiency and responsiveness
of the storage device [10-15]. Therefore, this research extends its focus beyond the analysis of cell current degradation
in 3D NAND Flash memory to the realm of program speed. To enhance the flexibility
of the investigation, a conventional 2D NAND structure was ingeniously transformed
into a cylindrical structure, providing a versatile platform for experimentation with
various channel designs [16-20].
II. SIMULATION
Fig. 1(a) shows a schematic diagram of 3D NAND Flash Memory and the cross-sectional to channel
profile of select word-lines (WLs) on 3D NAND flash memory, which consists of four
types of circles, ellipses, spikes, and double-spike designed in technology computer-aided
design (TCAD). The WL stack consisted of seven layers structured with alternating
oxides and nitrides, with each layer being 30 nm thick. The holes were fabricated
using a plug etch process and an oxide-nitride-oxide-polysilicon (ONOP) deposition
process. The detailed fabrication process is as follows. Selective etching was carefully
performed to remove the nitride layer to give a shape to the WL, followed by the detailed
deposition of the tunnel oxide, charge trap nitride, and blocking oxide layers to
improve the structural integrity of the memory cell. This process was performed using
the sentaurus process in the simulation. Finally, control gates were fabricated to
provide a means of manipulating charge storage and recovery mechanisms within the
NAND Flash memory. The detailed specifications are listed in Table 1. In each channel profile, a step-by-step program, V$_{th}$ was used to examine, the
properties of the E-Field of the tunneling oxide.
Fig. 2 shows the step-by-step programmed I$_{D}$-V$_{G}$ curves for each channel profile
of select WLs in 3D NAND Flash Memory. For (a) circle, (b) ellipse, (c) spike and
(d) double-spike profile, the selected WL was programmed within a voltage range of
12-18V, just before reaching the saturation region, while V$_{\mathrm{PASS}}$ was
consistently applied at 6 V in the unselected WL. Notably, each channel profile exhibited
variations in the E-field applied to the tunneling oxide when a programmed voltage
was applied, resulting in distinct distributions of trapped electrons within the nitride
layer. Consequently, as the devices were programmed from their initial states to 18
V, the V$_{th}$ differences vary depending on their structural characteristics. The
V$_{th}$ difference is most pronounced for the spike profile, measured at 3.3 V. It
is followed by the double-spike profile at 2.34 V, the ellipse profile at 1.79 V,
and the circle profile at 1.7 V.
Fig. 1. (a) Schematic diagram of 3D NAND Flash Memory string and cross-sectional to channel profile of select WLs in 3D NAND Flash Memory; (b) circle; (c) ellipse; (d) spike; (e) double-spike Schematic of 3D NAND flash memory string.
Fig. 2. Step-by-step programmed ID-VGcurves for each channel profile of the selected WL in 3D NAND flash memory: (a) circle; (b) ellipse; (c) spike; (d) double-spike.
Table 1. Physical And Material Parameters
|
Physical Parameter
|
Value
|
|
Gate Length (nm)
Gate Spacer Thickness (nm)
Tunneling Oxide Thickness (nm)
Nitride Thickness (nm)
Blocking Oxide Thickness (nm)
Polysilicon Channel Thickness (nm)
Filler Oxide Thickness (nm)
Trap energy level (Et)
Trap density (Nt)
|
30
30
4
8
8
15
23
2.5 eV
3e19 cm-3
|
III. RESULT AND DISCUSSIONS
Fig. 3 shows the E-field distribution along the cut-line in the circle and ellipse profiles
at two regions—}the ``A'' and ``B'' cut lines at V$_{\mathrm{PGM}}$=18 V. The application
of the programmed voltage results in a direct relationship between the E-field within
the tunneling oxide, the number of trapped electrons in the nitride, and the resulting
increase in V$_{th}$. Fig. 3(a) shows that the E-field is notably concentrated along the ``A'' cut-line of the ellipse
profile when compared to the circle profile. Conversely, in Fig. 3(b), the E-field along the cut-line diminishes within the area adjacent to the ``A''
cut-line when compared to the circle profile. The ellipse profile exhibits the highest
E-field concentration in the ``A'' cut-line with the largest radius of curvature,
while the adjacent region displays a relatively lower E-field. Consequently, the average
E-field within the circle profile closely mirrors that of the ellipse profile because
the overall E-field application remains similar despite variations in the E-field
distribution [21,22].
Fig. 4 shows the E-field distribution along the cut line in the spike and double-spike profiles
at V$_{\mathrm{PGM}}$=18V (a) a sharp protrusion region in the spike and double-spike
profiles, (b) a sharp protrusion region corresponding to the double-spike profile
and (c) a region adjacent to the sharp protrusion. The V$_{\mathrm{PGM}}$ leads to
a notable relationship between the E-field within the tunneling oxide, accumulation
of electrons in the nitride layer, and subsequent elevation of V$_{th}$. In Fig. 4(a), the E-field distribution along the cut line in the tunneling oxide is distinctly
concentrated at the sharp protrusion of the spike profile compared with the double-spike
profile. This is because, at the same program voltage of 18 V, the spike profile has
a larger V$_{th}$ than the double-spike profile, resulting in a higher E-field in
the tunneling oxide. Conversely, the sharp protrusion region specific to the double-
spike profile in Fig. 4(b) indicates a larger E-field within the tunneling oxide compared to the spike profile
without the sharp protrusion region. Additionally, the E-field was marginally greater
within the spike profile in the region where neither the spike profile nor the double-spike
profile corresponded to a sharp protrusion, as shown in Fig. 4(c). This is because the E-fields are all concentrated at the sharp protrusions in the
double-spike profile and the E-fields in the adjacent regions are less than those
in the spike profile. Consequently, a stronger E-field was applied to the tunneling
oxide of the spike profile.
Fig. 5 shows the V$_{th}$ slope according to the E-field of the tunneling oxide when a programmed
voltage is applied to each channel profile. It is evident that the E-field is most
pronounced in the spike profile and least pronounced in the circular profile when
a programmed voltage is applied before reaching the saturation region. V$_{th}$ increased
as the E-field of the tunneling oxide increased during the program operation of each
channel profile. Therefore, the V$_{th}$ slope as a function of the program voltage
and E-field shows the following order: spike profile {\textgreater} double-spike profile
{\textgreater} ellipse profile {\textgreater} circle profile. The results showed direct
correlation between the application of an increased E-field to the tunneling oxide,
enhanced electron trapping in the nitride, and an increase in V$_{th}$.
Fig. 3. E-field distribution along the cut-line in circle and ellipse profiles at VPGM=18 V: (a) "A" cut-line; (b) "B" cut-line.
Fig. 4. E-field distribution along cut-line in the spike and double spike profiles at VPGM=18 V: (a) sharp protrusion region in the spike and double spike profiles; (b) sharp protrusion region corresponding to the double spike profile; (c) region adjacent to the sharp protrusion.
Fig. 5. Vthslope according to the E-field of tunneling oxide when program voltage is applied in each channel profile.
IV. CONCLUSIONS
This study investigated the channel profile and program speed dynamics within non-ideal
vertical 3D NAND Flash Memory using advanced 3D TCAD simulations. The application
of the programmed voltage revealed a direct link between the E-field within the tunneling
oxide, electron trapping in the nitride layer, and subsequent V$_{th}$ elevation.
Different channel profiles yield varying E-field concentrations, which affect the
V$_{th}$ values. Each channel profile exhibits distinct E-field distributions within
the tunneling oxide when exposed to a programmed voltage. The observed E-field trends
aligned closely with V$_{th}$ variations as a function of program voltage. Higher
E-field application within the tunneling oxide corresponded to elevated V$_{th}$ values,
reaffirming the interplay between the E-field, electron trapping, and V$_{th}$. This
study underscores the significance of channel profiles in dictating the E-field distribution
and, consequently, the performance of 3D NAND Flash Memory.
ACKNOWLEDGMENTS
This study was supported by SK Hynix Inc.
References
Compagnoni, Christian Monzio, et al. "Reviewing the evolution of the NAND flash technology."
Proceedings of the IEEE 105.9 (2017): 1609-1633.
Micheloni, Rino, Seiichi Aritome, and Luca Crippa. "Array architectures for 3-D NAND
flash memories." Proceedings of the IEEE 105.9 (2017): 1634-1649.
Kang, Dongku, et al. "256 Gb 3 b/cell V-NAND flash memory with 48 stacked WL layers."
IEEE Journal of Solid-State Circuits 52.1 (2016): 210-217.
Nitayama, Akihiro, and Hideaki Aochi. "Vertical 3D NAND flash memory technology."
ECS Transactions 41.7 (2011): 15.
M. Kang, et al. "Improving read disturb characteristics by using double common source
line and dummy switch architecture in multi level cell NAND flash memory with low
power consumption." Japanese Journal of Applied Physics 50.4S (2011): 04DD03.
Y. Kim, et al. "Three-dimensional NAND flash architecture design based on single-crystalline
stacked array." IEEE Transactions on Electron Devices 59.1 (2011): 35-45.
Y. Kim, and M. Kang, "Down-coupling phenomenon of floating channel in 3D NAND flash
memory." IEEE Electron Device Letters 37.12 (2016): 1566-1569.
M. Kang, and Yoon Kim. "Natural local self-boosting effect in 3D NAND flash memory."
IEEE Electron Device Letters 38.9 (2017): 1236-1239.
S. Han, Y. Jeong, H. Jhon, and M. Kang. Investigation of inhibited channel potential
of 3D NAND flash memory according to word-line location. Electronics, 9.2 (2020):
268.
Bhatt, Upendra Mohan, et al. "Mitigating the impact of channel tapering in vertical
channel 3-D NAND." IEEE Transactions on Electron Devices 67.3 (2020): 929-936.
Kim, Kee Tae, et al. "The effects of taper-angle on the electrical characteristics
of vertical NAND flash memories." IEEE Electron Device Letters 38.10 (2017): 1375-1378.
K.-T. Park, et al. “Three-dimensional 128 Gb MLC vertical NAND flash memory with 24-WL
stacked layers and 50 MB/s high-speed programming.” IEEE Journal of Solid-State Circuits
50.1 (2014): 204-213.
A. Goda and P. Krishna. “Scaling directions for 2D and 3D NAND cells.” 2012 International
Electron Devices Meeting. IEEE, (2012): 2-1.
Lee, Jun Gyu, et al. "Effect of the blocking oxide layer with asymmetric taper angles
in 3-D NAND flash memories." IEEE Journal of the Electron Devices Society 9 (2021):
774-777.
Bhatt, Upendra Mohan, et al. "Mitigating the impact of channel tapering in vertical
channel 3-D NAND." IEEE Transactions on Electron Devices 67.3 (2020): 929-936.
D-G. Yoon, J-M. Sim, and Y-H. Song. “Mechanical stress in a tapered channel hole of
3D NAND flash memory.” Microelectronics Reliability 143 (2023): 114941.
A. Fayrushin, et al. “Numerical study of non-circular pillar effect in 3D-NAND flash
memory cells.” 2019 IEEE Workshop on Microelectronics and Electron Devices (WMED).
IEEE, 2019.
Y. Li, et al. “128Gb 3b/Cell NAND flash memory in 19nm technology with 18MB/s write
rate and 400Mb/s toggle mode.” 2012 IEEE International Solid-State Circuits Conference.
IEEE, 2012.
T-H. Hsu, et al. “A comprehensive study of double-density hemi-cylindrical (HC) 3-D
NAND flash.” IEEE Transactions on Electron Devices 67.12 (2020): 5362-5367.
L. Zhang, et al. “Modeling shortchannel effect of elliptical gate-allaround MOSFET
by effective radius.” IEEE Electron Device Letters 32.9 (2011): 1188-1190.
Sim, Jae-Min, Myounggon Kang, and Yun-Heub Song. "A novel program operation scheme
with negative bias in 3-D NAND flash memory." IEEE Transactions on Electron Devices
68.12 (2021): 6112-6117.
Lee, Inyoung, et al. "Investigation of Poly Silicon Channel Variation in Vertical
3D NAND Flash Memory." IEEE Access 10 (2022): 108067-108074.
Jaewoo Lee received B.S. degree in the department of electrical engi- neering,
Korea National University of Transportation, Korea, in 2022. From 2016 to 2022, He
is currently a master student at Korea National University of Transport. His current
research interests include operation conditions, reliability and cell characteristics
of 3D NAND Flash Memory.
Myounggon Kang received Ph.D. degree in the department of electrical engineering,
Seoul National Univer-sity, Seoul, Korea, in 2012. From 2005 to 2015, he worked as
a senior engineer at Flash Design Team of Samsung Electronics Company. In 2015, he
joined Korea National University of Transportation as a professor of Department of
Electronics Engineering. His current research interests are CMOS device modeling and
circuit design of memory.
Daewoong Kang received the Ph.D. degree in electrical engineering from Seoul National
University, Seoul, in 2009. From 2000 to 2015, he worked at Samsung Electronics Company
Ltd., Yongin-si, South Korea, where he was in charge of developing 2D/3D NAND flash
as a PI Principal Engineer. From 2015 to 2019, he worked as Senior Technologist (Principal)
in Western Digital Corporation (WDC), San Jose, U.S. From 2019 to 2022, he worked
as a NAND Product Vice President (VP) at SK-Hynix Semiconductor, Icheon-si, South
Korea, and developed the vertical NAND flash product with 128 layers for the first
time in the world. His current research interests include the NAND process integration,
cell characteristics, and reliability of 3D flash memory.
Seongjo Park has worked at SK hynix, Icheon-si, South Korea since 1995. He was
the manager of 2D/3D NAND process integration and product management office. He is
vice president of NAND develop-ment in charge of developing NAND products.
Yoocheol Shin received the M.S degree in physics from Seoul National University,
Seoul, in 1995. From 1995 to 2017, he worked at Samsung Electronics Company Ltd.,
Yongin-si, South Korea, where he was in charge of developing 2D/3D NAND flash as a
Fail Analysis Principal Engineer. In 2018, he joined SK hynix, Icheon-si, South Korea.
He is in charge of developing 3D NAND flash process integration as Process Principal
Engineer.
Yungjun Kim received the M.S. degree in physics from Korea University, Seoul,
in 2010, He has been working as a Device and Process Integration Engineer in the field
of 2D/3D NAND flash memory at SK hynix, Icheon-si, South Korea, since 2010, and he
is currently working on Ph.D, degree from Korea Advanced Institute of Science and
Technology(KAIST) Graduate School of Semiconductor Technology. His current research
interests include Ferroelectric and 3D NAND.
Hojong Kang received M.S. degree in the department of physics, Chungbuk National
University, Cheongju, South Korea, in 2012, where he developed room-tem-perature charge
stability modulated by quantum effect in CMOS based silicon island for the first in
the world. From 2013 to 2022, he worked as senior engineer at 3D NAND flash Process
Integration Team of Samsung Electronics Company Ltd., Youngin-si, Korea. In 2024,
he joined Sk hynix, Icheon-si, South Korea, and he is in charge of developing 3D NAND
flash process integration as Senior Engineer