I. INTRODUCTION
Recently, as the size of the semiconductor devices has decreased, the short-channel
effects (SCEs) has appeared in the metal-oxide-semiconductor field-effect transistors
(MOSFETs) [1-4]. Also, a subthreshold swing (SS) of the MOSFET is limited to 60 mV/decade at a room
temperature. However, because a tunneling field-effect transistor (TFET) operates
by the band-to-band-tunneling (BTBT), it has the immunity to the SCEs and the SS under
60 mV/dec [5-8]. Also, the poly-Si can be applied to 3-dimensional vertical stacking, and is advantageous
in terms of manufacturing process technology. In addition, it can replace the silicon-on-insulator
(SOI) structure of the high fabrication cost. In this study, the multiple nanosheet
structure based on the polycrystalline silicon (poly-Si) is used to improve the I$_{\mathrm{on}}$
of the TFET and to suppress the SCE. These multiple nanosheet tunneling field-effect
transistors (MNSTFETs) based on the poly-Si can compensate for the low I$_{\mathrm{on}}$
of TFET. Because the poly-Si is adapted in these devices, it is important to analyze
the grain boundary (GB)’s effects. [9,10]
In this study, we present the electrical performances of the MNSTFETs depending on
the GB-locations. Also, we compare the electrical characteristics of the MNSTFETs
and the MNSMOSFETs based on the poly-Si [11].
II. DEVICE STRUCTURE AND SIMULATION METHOD
Fig. 1 shows the 3-dimensional view and the cross-sectional view of the MNSTFET based on
the poly-Si [12]. The poly-Si was used as a material for the nanosheet channels, and the gate length
(L$_{\mathrm{g}}$), the nanosheet width (W$_{\mathrm{sh}}$), and the nanosheet total
width (W$_{\mathrm{total}}$) are 16, 30, and 76 nm, respectively. The gate insulator
(HfO$_{2}$/SiO$_{2}$) thickness (T$_{\mathrm{ox}}$) is 1.1/0.3 nm, and SiO$_{2}$ was
used as the interfacial layer. The doping concentrations of the source, channel, and
drain regions are 1 ${\times}$ 10$^{20}$ cm$^{-3}$ (p-type), 1 ${\times}$ 10$^{16}$
cm$^{-3}$ (n-type), and 1 ${\times}$ 10$^{19}$ cm$^{-3}$ (n-type), respectively. The
parameters of the proposed device are summarized in Table 1. The I$_{\mathrm{on}}$ is defined as the drain current (I$_{\mathrm{DS}}$) when the
gate voltage (V$_{\mathrm{GS}}$) is 1.0 V and the drain voltage (V$_{\mathrm{DS}}$)
is 0.7 V. The I$_{\mathrm{off}}$ is defined as the I$_{\mathrm{DS}}$ when the V$_{\mathrm{GS}}$
= 0.0 V and the V$_{\mathrm{DS}}$ = 0.7 V. The V$_{\mathrm{T}}$ is defined as the
gate voltage when the I$_{\mathrm{DS}}$ = 0.1 ${\mu}$A/${\mu}$m. The average of subthreshold
swing (SS$_{\mathrm{ave}}$) is defined as the inverse of the average slope between
two points where the I$_{\mathrm{DS}}$ is I$_{\mathrm{off}}$ and 0.1 ${\mu}$A/${\mu}$m.
Fig. 2(a) shows the I$_{\mathrm{DS}}$-V$_{\mathrm{GS}}$ simulation curves fitted by the experimental
data in [13] to accurately implement the tunneling model. The trap distribution in the grain boundary
(GB) of the poly-Si was extracted from experimental data from [14], as shown in Fig. 2(b). The GB has both the donor-like traps and the acceptor-like traps. This device was
simulated by the Sentaurus technology computer-aided design (TCAD) tool. These simulations
include the dynamic nonlocal BTBT model, the bandgap narrowing model, the Fermi-Dirac
model, the Shockley-Read-Hall recombination model, the trap-assisted Auger recombination
model, and the multivalley (MLDA) model to increase the accuracy of the simulation
[15].
Fig. 1. The 3-dimensional view and the cross-sectional view of the MNSTFET based on the poly-Si.
Fig. 2. (a) The I$_{\mathrm{DS}}$-V$_{\mathrm{GS}}$ simulation curves fitted by the experimental data in[13]to implement the tunneling model. (b) The GB trap distribution extracted from the experimental data in[14].
Table 1. Parameters for the MNSTFET based on the poly-Si
|
Parameter
|
Value
|
|
Gate length (Lg)
|
16 nm
|
|
Spacer length (Lsp)
|
6 nm
|
|
Extension source/drain length (Lsd)
|
8.5 nm
|
|
Channel thickness (Tch)
|
8 nm
|
|
Spacer thickness (Tsp)
|
10 nm
|
|
Gate insulator (HfO2/SiO2) thickness (Tox)
|
1.1 / 0.3 nm
|
|
Nanosheet width (Wsh)
|
30 nm
|
|
Nanosheet total width (Wtotal)
|
76 nm
|
|
p+ - Source doping concentration
|
1 × 1020 cm-3
|
|
n - Channel doping concentration
|
1 × 1016 cm-3
|
|
n+ - Drain doping concentration
|
1 × 1019 cm-3
|
III. RESULTS AND DISCUSSION
Fig. 3(a)-(f) show the cross-sections of the MNSTFETs based on the poly-Si depending on the
GB-locations. These devices have 3 nanosheets and they have 1 GB on each nanosheets
except the case (f). Fig. 3(f) shows the device based on the single crystalline silicon without the GB. Fig. 4 is the transfer curves of the MNSTFETs for Fig. 3(a)-(f) cases, which are normalized with the W$_{\mathrm{total}}$. Table 2 summarizes the electrical characteristics of Fig. 4. Fig. 5(a) is the energy band diagrams of the MNSTFETs depending on the GB locations when the
V$_{\mathrm{GS}}$ = 1 V. Fig. 5(b) is the energy band diagrams with enlarged the red boxes of Fig. 5(a). In Table 2, the I$_{\mathrm{on}}$ and the V$_{\mathrm{T}}$ in the case of x = 9 nm have the
largest difference with 26.8\% and 5.0\%, respectively, compared with the case without
the GB. The thicker the tunneling barrier, the more difficult it is for electrons
to tunnel. The tunneling barrier for x = 9 nm is the thickest as shown as in Fig. 5(a) and it makes the I$_{\mathrm{on}}$ smaller and V$_{\mathrm{T}}$ larger. The tunneling
barrier is thick because the sharp band peak is created due to electrons trapped in
the GB as shown in Fig. 5(b). Therefore, the I$_{\mathrm{on}}$ is the lowest and the V$_{\mathrm{T}}$ is the largest.
However, as shown in Fig. 5(b), when the GB location varies from 9 nm to 14, 19, and 24 nm in order, the sharp band
peak gradually moves away from the tunneling region. This reduces the interference
of the electron flow, so that the I$_{\mathrm{on}}$ increases and the V$_{\mathrm{T}}$
decreases, which is similar to the values in the case without the GB. Fig. 6(a) is the energy band diagrams of the MNSTFETs depending on the GB locations when the
V$_{\mathrm{GS}}$ = 0 V. Fig. 6(b) is the energy band diagrams with enlarged the red boxes of Fig. 6(a). As shown in Table 2, the I$_{\mathrm{off}}$ and the average of subthreshold swing (SS$_{\mathrm{ave}}$)
in the case of x = 24 nm have the largest difference of 49.2\% and 38.7\%, respectively,
compared with the case without the GB. This is because the trap-assisted-tunneling
(TAT) occurs when x = 24 nm. Fig. 6(a) shows that when x = 24 nm, it is the region where the TAT can occur. As shown in
Fig. 6(b), when x = 24 nm, the energy band rises to the top due to the electrons trapped in
the GB. The electrons are tunneled through these traps, and they result in high leakage
current at an off-state. And the SS$_{\mathrm{ave}}$ is the largest value of 104.0
mV. Fig. 7(a) and (b) show the distribution of the electrons and holes trapped in the GB of the
MNSTFETs when V$_{\mathrm{GS}}$ are 1.0 V and 0.0 V, respectively, depending on the
GB locations. The energy band where the GB is located rises because the number of
electrons trapped in the GB is larger than the number of holes. Thus, the energy band
rises upwards, acting as if a negative voltage is applied.
We have compared the electrical characteristics of MNSTFETs and MNSMOSFETs. Fig. 8 shows the transfer curves of MNSMOSFETs based on the poly-Si depending on the GB-locations.
The structure, the materials, and the GB locations of the MNSMOSFETs are the same
as those of the MNSTFETs. Their doping concentrations in the source, channel, and
drain regions are 1 ${\times}$ 10$^{19}$ cm$^{-3}$ (n-type), 1 ${\times}$ 10$^{17}$
cm$^{-3}$ (p-type), and 1 ${\times}$ 10$^{19}$ cm$^{-3}$ (n-type), respectively. In
Fig. 9(a) and (b) compares the SS$_{\mathrm{min}}$ and the SS$_{\mathrm{ave}}$ of the MNSTFETs
and the MNSMOSFETs depending on the GB locations. As shown in Fig. 9(a), the SS$_{\mathrm{min}}$’s for the MNSTFETs are smaller than those for the MNSMOSFETs.
This is because the TFET uses tunneling mechanism and the MOSFET uses drift mechanism.
Also, as shown in Fig. 9(b), the SS$_{\mathrm{ave}}$’s of MNSTFETs has a smaller effect depending on the GB locations
than those of the MNSMOSFETs except for the case of x = 24 nm. In the case of MOSFET,
the electrons trapped in the GB act the same as applying a negative voltage to the
gate, interrupting channel formation [11]. And it makes the SS$_{\mathrm{ave}}$ deviation larger depending on the GB locations.
But, in the case of TFET, it is only affected when the GB is located in the TAT region.
Therefore, if the GB is not located at 24 nm, the electrical characteristics of the
MNSTFET depending on the GB locations are superior to those of the MNSMOSFET.
The poly-Si has the random distribution of the GB. Therefore, it is necessary to compare
the characteristics of the MNSTFET and the MNSMOSFET by varying the GB location in
each sheet. Fig. 10(a) and (b) show the histogram of the V$_{\mathrm{T}}$ and the SS$_{\mathrm{ave}}$ of
the MNSTFETs and the MNSMOSFETs extracted from 125 (= 5 ${\times}$ 5 ${\times}$ 5)
samples. The GB is located at one of the following locations on each sheet: 4, 9,
14, 19, and 24 nm. The total number of sheets of this device is 3, and each sheet
has one GB. Fig. 10(c) shows a histogram of SS$_{\mathrm{ave}}$ of the MNSTFETs and the MNSMOSFETs extracted
from 64 (= 4 ${\times}$ 4 ${\times}$ 4) samples except for the case of x = 24 nm in
Fig. 10(b). The GB is located at one of the following locations on each sheet: 4, 9, 14, and
19 nm. The standard deviation (SD) is a value indicating how far the data are spread
around the mean. The relative standard deviation (RSD) is the SD divided by the mean
and multiplied by 100. The small RSD means that the SD is relatively small compared
with the mean, so the
dispersion is small. In Fig. 10(a), the means of the extracted V$_{\mathrm{T}}$’s of the MNSTFETs and the MNSMOSFETs
are 0.412 V and 0.206 V, respectively. The SDs are 3.90 mV and 8.31 mV, respectively.
The RSDs are 0.95\% and 4.03\%, respectively. For the same reason as described for
SS$_{\mathrm{ave}}$ in Fig. 9(b), the electrons trapped in the GB interfere with channel formation. So, the SD and
RSD of the MNSTFET are smaller than those of the MNSMOSFET. In Fig. 10(b), the means of the extracted SS$_{\mathrm{ave}}$’s of the MNSTFETs and the MNSMOSFETs
are 72.7 mV/dec and 70.5 mV/dec, respectively. The SDs are 7.08 mV/dec and 4.00 mV/dec,
respectively. The RSDs are 9.75\% and 5.67\%, respectively. The SS$_{\mathrm{ave}}$’s
of the MNSTFETs have a larger dispersion than those of the MNSMOSFETs. However, as
shown in Fig. 10(c), except for the case of x = 24 nm, the means of the extracted SS$_{\mathrm{ave}}$’s
of the MNSTFETs and the MNSMOSFETs are 67.2 mV/dec and 72.4 mV/dec, respectively.
The SDs are 1.50 mV/dec and 4.16 mV/dec, respectively. The RSDs are 2.24\% and 5.74\%,
respectively. If the GB is not located at 24 nm, the MNSTFET is better than the MNSMOSFET
in terms of the I$_{\mathrm{off}}$, the V$_{\mathrm{T}}$, and the SS$_{\mathrm{ave}}$.
Therefore, when fabricating the MNSTFET device, it is important to control the process
so that the GB is not located in the drain region.
Table 2. The transfer characteristics of the MNSTFET depending on GB-locations
|
x =
|
Ion [μA/μm]
|
Ioff[fA/μm]
|
VT [V]
|
SSmin [mV/dec]
|
SSave[mV/dec]
|
|
4 nm
|
27.05
|
5.75
|
0.412
|
42.0
|
64.9
|
|
9 nm
|
23.40
|
7.38
|
0.425
|
43.1
|
68.9
|
|
14 nm
|
27.44
|
5.70
|
0.414
|
41.7
|
66.6
|
|
19 nm
|
28.57
|
5.96
|
0.407
|
40.2
|
69.5
|
|
24 nm
|
28.65
|
12.22
|
0.405
|
40.9
|
104.0
|
|
w/o GB
|
29.67
|
6.21
|
0.404
|
42.8
|
63.8
|
Fig. 3. (a) to (f) The cross-sections of the MNSTFET based on the poly-Si depending on GB-locations.
Fig. 4. The transfer curves of the MNSTFET based on the poly-Si depending on GB-locations.
Fig. 5. (a) The energy band diagram of the MNSTFET depending on GB-locations when V$_{\mathrm{GS}}$ is 1 V; (b) The energy band diagram with enlarged of the red boxes in Fig. 5(a). The energy bands are extracted at the 2 nm below the gate insulator along the A-A’ line.
Fig. 6. (a) The energy band diagram of the MNSTFET depending on GB-locations when V$_{\mathrm{GS}}$ is 0 V; (b) The energy band diagram with enlarged of the red boxes in Fig. 6(a).
Fig. 7. The distribution of electrons and holes trapped in the GB of the MNSTFET depending on GB-locations when V$_{\mathrm{GS}}$ is (a) 1 V; (b) 0 V, respectively. The electrons and holes trapped in GB are extracted at the 2 nm below the gate insulator along the A-A’ line.
Fig. 8. The transfer curves of the MNSMOSFET based on the poly-Si depending on GB-locations.
Fig. 9. (a) SS$_{\mathrm{min}}$; (b) SS$_{\mathrm{ave}}$ of the MNSTFET and the MNSMOSFET based on the poly-Si depending on GB-locations.
Fig. 10. The histograms of (a) the V$_{\mathrm{T}}$’s; (b) the SS$_{\mathrm{ave}}$’s of the MNSTFETs and the MNSMOSFETs extracted from 125 (= 5 ${\times}$ 5 ${\times}$ 5) samples; (c) The histogram of SS$_{\mathrm{ave}}$’s of the MNSTFETs and the MNSMOSFETs extracted from 64 (= 4 ${\times}$ 4 ${\times}$ 4) samples except for the case when the GB is at 24 nm in Fig. 10(b).
IV. CONCLUSIONS
This study showed the transfer performances depending on the GB-locations within a
sheet in the MNSTFET based on the poly-Si. As a result of the analysis, the largest
V$_{\mathrm{T}}$ was shown for the case of x = 9 nm, and the largest SS$_{\mathrm{ave}}$
was shown for the case of x = 24 nm due to the TAT. In addition, the electrical characteristics
of 125 samples of the MNSTFETs were compared with the MNSMOSFETs. If the GB was not
located at 24 nm, the MNSTFET was better than the MNSMOSFET in terms of the I$_{\mathrm{off}}$,
the V$_{\mathrm{T}}$, and the SS$_{\mathrm{ave}}$. Consequently, this simulation showed
that the MNSTFET has smaller effect on the GB location than the MNSMOSFET.
ACKNOWLEDGMENTS
This work was supported by the National Research Foundation of Korea (NRF) grant
funded by the Korea government (MSIT) (No. NRF-2020R1A2C1005087). This study was supported
by the BK21 FOUR project funded by the Ministry of Education, Korea (4199990113966).
This research was supported by Basic Science Research Program through the National
Research Foundation of Korea (NRF) funded by the Ministry of Education (NRF-2021R1A6A3A13039927).
This research was supported by National R&D Program through the National Research
Foundation of Korea (NRF) funded by Ministry of Science and ICT (2021M3F3A2A03017764).
This research was supported by National R&D Program through the National Research
Foundation of Korea (NRF) funded by Ministry of Science and ICT (2022M3I7A1078936).
This investigation was financially supported by Semiconductor Industry Collaborative
Project between Kyungpook National University and Samsung Electronics Co. Ltd. The
EDA tool was supported by the IC Design Education Center (IDEC), Korea.
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Ga Eon Kang received a B.Sc. degree in electronic engineering from the School of
Electronics Engi-neering (SEE), Kyungpook National University (KNU), Daegu, South
Korea, in 2022, where she is currently pursuing a M.S. degree in electronic and electrical
engineering. Her research interests include the design, fabrication, and characterization
of GaN devices and tunneling FETs.
Sang Ho Lee received a B.Sc. degree in electronics engineering from the School
of Electronics Engineering (SEE), Kyungpook National University (KNU), Daegu, South
Korea, in 2019, where he is currently pursuing a Ph.D. in electronic and electrical
engineering with the SEE. His research interests include the design, fabrication,
and characterization of gate-all-around logic devices and capacitor-less 1T-DRAM transistors.
Jin Park received a B.Sc. degree in electronic engineering from the School of Electronics
Engineering (SEE), Kyungpook National Univer-sity (KNU), Daegu, South Korea, in 2020,
and a M.Sc. degree from the school of electronic and electrical Engineering (SEE),
Kyungpook National University (KNU), where she is currently pursuing a Ph.D. in electronic
and electrical engineering. Her research interests include the design, fabrication,
and characterization of gate-all-around logic devices and capacitor-less 1T-DRAM transistors.
So Ra Min received a B.Sc. degree in Electronic Engineering from the School of
Electronics Engineering, Yeungnam University (YU), Gyeong-san, North Gyeongsang, South
Korea, in 2020, where she is currently pursuing a M.Sc. degree in school of Electronic
and Electrical Engineering. Her research interests include the design, fabrication,
and characterization of GaN devices and capacitor-less 1T-DRAM transistors.
Geon Uk Kim received a B.Sc. degree in electronic engineering from the School of
Electronics Engi-neering (SEE), Kyungpook National University (KNU), Daegu, South
Korea, in 2021, where he is currently pursuing an M.S. degree in electronic and electrical
engineering. His research interests include the design, fabrication, and characterization
of GaN devices and capacitor-less 1T-DRAM transistors.
Jun Hyeok Heo received a B.Sc. degree in electronic engineering from the School
of Electronics and Information Engineering, Korea University (KU) Sejong Campus, Sejong-si,
South Korea, in 2021, where he is currently pursuing an M.S. degree in electronic
and electrical engineering. His research interests include the design, fabrication,
and characterization of vertical GaN power devices.
Jae Won Jang received the B.S. and M.S degrees in electrical engineering from Korea
University, Seoul, Korea in 2006 and 2008, respectively. In 2013, Jaewon Jang received
Ph.D degrees in electrical engineering and computer sciences from University of California
at Berkeley, CA, USA. From 2013 to 2014, he was a post doctorial researcher, and working
for developing of high-performance metal oxide transistors by printing technology.
From 2015 to 2016, he was a researcher and working for developing of high performance
organic thin film transistor in Samsung Advanced Institute and Technology, Suwon,
Korea. Since 2016, he has been with Kyungpook National University, Daegu, Korea, where
he is currently an assistant professor with the School of Electronics Engineering.
Jin-Hyuk Bae received a B.S. degree in Electronics and Electrical Engineering from
Kyungpook Na-tional University, Daegu, Korea in 2004, and M.S. and Ph.D. degrees in
Electrical Engineering from the Seoul National University, Seoul, Korea in 2006 and
2010, respectively. For the period from 2010 to 2012, he worked as a post-doctoral
research fellow with Ecole Nationale Superiere des Mines de Saint-Etienne, Gardanne,
France. In 2012, he joined the faculty in the School of Electronics Engineering, Kyungpook
National University, Korea, where he is currently an Associate Professor. His research
interests include interfacial engineering and physics of organic based and metal-oxide-based
electronic devices and their sensor applications.
Sin-Hyung Lee received his B.S. and Ph.D. degrees in electrical engineering from
Seoul National University, Korea in 2013 and 2019, respectively. He is currently an
assistant professor in the School of Electronics Engineering at Kyung-pook National
University in Republic of Korea. His research covers the neuromorphic electronics,
artificial synapse, memristors, and organic electronics.
In Man Kang received the B.S. degree in electronic and electrical engineering from
School of Elec-tronics and Electrical Engineering, Kyungpook National University (KNU),
Daegu, Korea, in 2001, and the Ph.D. degree in electrical engin-eering from School
of Electrical Engineering and Computer Science (EECS), Seoul National University (SNU),
Seoul, Korea, in 2007. He worked as a teaching assistant for semiconductor process
education from 2001 to 2006 at Inter-university Semiconductor Research Center (ISRC)
in SNU. From 2007 to 2010, he worked as a senior engineer at Design Technology Team
of Samsung Electronics Company. In 2010, he joined KNU as a full-time lecturer of
the School of Electronics Engineering (SEE). Now, he is currently working as an associate
professor. His current research interests include CMOS RF modeling, silicon nanowire
devices, tunneling transistor, low-power nano CMOS, and III-V compound semiconductors.
He is a member of IEEE EDS.