I. INTRODUCTION
Tunnel field-effect transistor (TFET) is considered to be a promising energy-efficient
switching device since they can achieve under 60 mV/decade subthreshold swing (SS)[1]. Carrier injection mechanism in TFETs relies on band-to-band tunneling from the source
to the channel. It has been reported that tunneling rate of carriers from source to
channel is inversely proportional to the band gap of channel materials[2]. Therefore, a material having a small band gap is preferred to increase the current
of TFET. Recently, extensive researches have been carried out to improve the on-current.
Various materials have been investigated to reduce the tunneling barrier width and
height[3-5]. Generally, Si-TFETs exhibit low on-current due to large band gap. In order to overcome
large tunneling barrier, SiGe, which has a smaller band gap than that of Si, is a
good alternative. In addition, SiGe is complementary MOS (CMOS) compatible because
it is a group IV material[6]. Although high Ge content is preferred for improving the on-current, it is contradictory
to the process capability due to the crystal lattice mismatch with Si substrate. Generally,
interface problem arises when SiGe having a high content of Ge is directly grown on
Si substrate. Dislocation lines starting from interface between Si substrate and SiGe
channel are shown in Fig. 1.
Fig. 1. Threading dislocation lines found at the junction of SiGe and Si due to different
lattice constants.
These lines act as trap sites on the surface and degrade the mobility of carriers
when current flows through the SiGe channel. To reduce the threading dislocation density
(TDD) caused by the lattice mismatch, some studies have been conducted to form a trap-less
channel with thick lattice matched-buffer layer[7,8]. However, there are two problems with the thick buffer layer. First, in terms of
the fabrication of a transistor, additional works are required to block the leakage
path to the buffer layer. For example, it needs additional blanket stacks (SiGe/Ge/SiGe)
to match lattice constant with virtual substrate[9], which is not suitable for modern CMOS which requires thin body. Also, the thick
body requires additional groundplane doping to suppress body leakage. When a TFET
is fabricated, it is necessary to reduce the body leakage in the subthreshold region
to obtain a low subthreshold swing (SS)[10]. Second, when the thicker crystal layer is grown, the cost increases in proportion
to the thickness. In this paper, to solve the abovementioned problems, we have proposed
the formation method of a SiGe nanowire channel with graded Ge concentration. The
proposed SiGe channel has high Ge concentration (about 40%) at the channel surface
to boost on-current, while Ge content is low at the interface between SiGe and Si
substrate to reduce the dislocation. To verify the proposed method, TCAD simulations
have been performed.
II. PROPOSED FABRICATION PROCESS
The proposed nanowire device can be fabricated by the process of Fig. 2. The feasibility of the structure is verified by three dimensional (3D) TCAD process
simulation as shown in Fig. 2. A two-step oxidation method (Fig. 3) is used to make a nanowire with graded Ge concentration. After active regions having
narrow fins are formed by e-beam lithography, the first oxidation is performed for
rounding the channel. The edges of the rectangular-shaped channel become rounded because
the oxidation rate at the corner is faster than that on the flat surface. The Si atoms
at the corner are more likely to encounter an oxygen molecule, so the oxidation rate
is faster at the corner. The temperature and time for the first oxidation should be
selected appropriately. Otherwise, the rounded shape may not be formed or the Si may
be exhausted during the oxidation as can be seen in the process simulations of Fig. 4. After the first oxidation, the oxide layer which is formed by the first oxidation
process is removed. Then, the epitaxial growth of 30-nm thick SiGe layer with 20%
Ge concentration is carried out. Second oxidation process, called Ge condensation,
is conducted. Here, the temperature at which the oxidation rate of Si is higher than
that of Ge should be selected. When the Si atoms in the SiGe are selectively oxidized,
the Ge diffuses into the Si channel and the Ge concentration near the channel surface
increases. This Ge condensation is experimentally proved by 5 minutes oxidation under
an oxygen atmosphere at 950˚C. Energydispersive x-ray spectroscopy (EDS) of Fig. 5 shows that the initial Ge content is about 20% and the Ge content of the channel
surface reaches to ~40% after Ge condensation. The oxide layer formed by the second
oxidation process can be used as a buffer layer in subsequent processes without stripping,
and the remaining processes can be performed using the gate-last process as depicted
in Fig. 2.
Fig. 2. Proposed device structure and process flow.
Fig. 3. Fabrication method of Ge condensed SiGe channel (a) Active pattern with e-beam
lithography, (b) 1st oxidation for wire rounding and dHF strip, (c) Epitaxial growth
of SiGe with low Ge mole fraction, (d) 2nd oxidation called Ge condensation.
Fig. 4. (a) Active Si (90 nm Width and 70 nm height) before first oxidation process,
(b) Shape of active Si after oxidization, (c) Oxide thickness with various temperatures
and times.
Fig. 5. Energy-dispersive x-ray spectroscopy profiles of SiGe channels.
III. SIMULATION RESULT
TFET with concentration-graded SiGe channel is simulated. Based on the EDS data of
Fig. 5, Ge content is set to decrease linearly from the surface (Fig. 6). A SiGechannel TFET without Ge condensation and a Si-channel TFET are used as a
control group. To simulate band to band tunneling (BTBT) generation rate (G) per unit
volume at uniform electric field limit, Kane’s model is used. The coefficients in
the model are obtained from the experimental data[11]. The physical parameters of the TFETs used in this simulation are shown in Table 1. Fig. 7 indicates the 2D cross-sectional structure of the simulated TFETs. A nanowire TFET
is simulated by rotating about the bottom of the Si substrate. The DC characteristics
of the proposed TFET are compared to those of the SiGe-channel TFET without Ge condensation
and the Si-channel TFET. Fig. 8 demonstrates that the proposed TFET has enhanced Ion and steeper SS although there
is a small amount of Ioff increase. In the case of TFETs which has a fatal disadvantage
of a low driving current, the small increase of Ioff is acceptable if the driving
current and SS can be enhanced at the same time because Ioff can be reduced by adjusting
the underlap and drain doping[12]. The enhanced Ion and steeper SS result from the reduction of band gap with the help
of Ge condensation since the tunneling are predominantly generated near the channel
surface in TFETs. Fig. 9(a)-(c) show that the number of the generated tunneling carriers increases as the Ge concentration
near the channel becomes higher.
Fig. 5. Energy-dispersive x-ray spectroscopy profiles of SiGe
channels.
Fig. 6. The Ge contents of the SiGe channel used in the simulation tool based on experimental
EDS data.
Table 1. List of physical parameters used in simulation
|
Parameter
|
Value
|
|
LGate
|
0.1 $\mu$m
|
|
EOT
|
1 nm
|
|
Underlap
|
20 nm
|
|
TSiGe
|
30 nm
|
|
TSi
|
10 nm
|
|
NDrain
|
1×1020 cm-3
|
|
NSource
|
1×1020 cm-3
|
|
NBody
|
1×1017 cm-3
|
Fig. 7. Simulated TFET structures (a) SiGe with surface Gerich and gradually decreasing
content from channel surface, (b) SiGe TFET with constant Ge content (The structure
was drawn in 2D, and then rotated around the bottom of the Si substrate to form a
nanowire structure).
Fig. 8. Transfer curves of SiGe TFETs with and without Ge condensation and Si channel
TFET.
Fig. 9. Contour Diagrams of electron band to band tunneling
generation according to Ge content in SiGe channel.
IV. CONCLUSION
In this study, the TFET with Ge-condensed SiGe nanowire channel is proposed to improve
Ion and SS simultaneously. The proposed nanowires are formed by the two step oxidation
processes; The first oxidation is the edge-rounding oxidation of rectangular-shape
Si channel and the second oxidation is the Ge condensation oxidation. Based on the
process and device simulations, it is concluded that the enhanced Ion and SS result
from the reduction of band gap with the help of Ge condensation at the channel surface.
ACKNOWLEDGMENTS
This work was supported by the Brain Korea 21 Project in 2018, in part by the Future
Semiconductor Device Technology Development Program (10067739 & 10080575) funded
by Ministry of Trade, Industry and Energy (MOTIE) and Korea Semiconductor Research
Consortium (KSRC), and in part by Synopsys Inc.
REFERENCES
Choi W. Y., et al , Aug. 2007, Tunneling Field-Effect Transistors (TFETs) With Subthreshold
Swing (SS) Less Than 60 mV/dec, IEEE Electron Device Lett., Vol. 28, pp. 743-745
Patel N., Ramesha A., Dec. 2008, Drive current boosting of ntype tunnel FET with strained
SiGe layer at source, Microelectronics Journal, Vol. 39, pp. 1671-1677
Lee M., et al , Oct. 2011, Driving Current Enhancement of Strained Ge (110) p-Type
Tunnel FETs and Anisotropic Effect, IEEE Electron Device Lett., Vol. 32, pp. 1355-1357
Moselund K., et al , Oct. 2012, InAs–Si Nanowire Heterojunction Tunnel FETs, IEEE
Electron Device Lett., Vol. 33, pp. 1453-1455
Zhou G., et al , Jun. 2012, InGaAs/InP Tunnel FETs With a Subthreshold Swing of 93
mV/dec and ION/IOFF Ratio Near 106, IEEE Electron Device Lett., Vol. 33, pp. 782-784
Wang W., et al , Jan. 2014, Design of U-Shape Channel Tunnel FETs With SiGe Source
Regions, IEEE Trans. Electron Devices, Vol. 61, pp. 193-197
Herzog H. J., et al , Dec. 2000, SiGe-based FETs:buffer issues and device results,
Thin Solid Films, Vol. 380, pp. 36-41
Dube A., et al , 2016, Strain Relaxed Silicon Germanium Buffer Layers: From Growth
to Integration Challenges, ECS Transactions, Vol. 75, No. 8, pp. 599-604
Witters L., et al , Nov. 2017, Strained Geranium Gate-All-Around pMOS Device Demonstration
Using Selective Wire Release Etch Prior to Replacement Metal Gate Deposition, IEEE
Trans. Electron Devices, Vol. 64, pp. 4587-4593
Kim S. H., et al , Jul. 2010, Impact of Body Doping and Thickness on the Performance
of Germanium-Source TFETs, IEEE Trans. Electron Devices, Vol. 57, pp. 1710-1713
Lee J., et al , Jun. 2016, Analysis on temperature dependent current mechanism of
tunnel field-effect transistors, Japanese Journal of Applied Physics, Vol. 55, No.
6S1, pp. 06GG03-1-06GG03-4
Chattopadhyay A., Mallik A., Mar. 2011, Impact of a Spacer Dielectric and a Gate Overlap/Underlap
on the Device Performance of a Tunnel Field-Effect Transistor, IEEE Trans. Electron
Devices, Vol. 58, pp. 677-683
Author
was born in Changwon, Korea, in 1987.
He received the B.S degree in Electrical Engineering from Seoul National University
in 2013.
He is currently working toward Ph.D degree in electrical engineering.
His research interests include nanoscale devices, tunnel field-effect transistor (TFET).
Mr. Lee is a Student Member of the Institute of Electrical and Electronics Engineers
(IEEE) and the Institute of Electronics Engineers of Korea (IEEK).
received the B.S. degree in 2014 from SungKyunKwan University (SKKU), Suwon, Korea.
He is currently working toward the Ph.D. degree in electrical engineering from Seoul
National University (SNU), Seoul, Korea.
His research interests include silicon nanowire biosensors and tunnel field-effect
transistor (TFET).
was born in Busan, Korea, in 1991.
He received a B.S. degree at Seoul National University (SNU) in 2014.
Currently, he is studying for a Ph.D. degree in electrical engineering at SNU.
His research interests include silicon nanowire biosensors and tunnel field-effect
transistor (TFET).
received the B.S degrees in 2010 from Seoul National University (SNU).
He is currently working toward the Ph.D. degree in Electrical Engineering at Seoul
National University (SNU), Seoul, Korea.
His current research interests include the ultra-low-power multi-channel transistors,
tunnel FET, GaN based LEDs.
Mr. Park is a Student Member of the Institute of Electrical and Electronics Engineers
(IEEE) and the Institute of Electronics Engineers of Korea (IEEK).
was born in Suwon, Korea, in 1992.
He received a B.S. degree at Seoul National University (SNU) in 2016.
Currently, he is studying for a M.S. degree in electrical engineering at SNU.
His research interests include 1T DRMA and steep switching devices using thyristor.
was born in Seoul, Korea, in 1992.
He received B.S degree from Seoul National University in 2016.
He is currently working toward Ph.D degree in electrical engineering from Seoul National
University (SNU), Seoul, Korea.
His research interests include tunnel field-effect transistor (TFET) and gate-all-around
(GAA) FET.
was born in Daegu, South Korea, in 1983.
He received the B.S., M.S., and the Ph.D. degrees in electrical engineering from Seoul
National University, Seoul, South Korea, in 2006, 2008, and 2014, respectively.
Since 2017, he has been a Faculty Member with Ajou University, Suwon, South Korea,
where he is currently an Assistant Professor with the Department of Electrical and
Computer Engineering.
received his B.S. and M.S. degrees in electronics engineering from Seoul National
University (SNU) in 1982 and 1984, respectively, and his Ph.D. degree in electrical
engineering from Stanford University in 1990.
From 1990 to 1993, he worked at the AT & T Bell Laboratories, where he contributed
to the development of 0.1 micron CMOS and its characterization.
From 1993 to 1994, he was with Texas Instruments, developing 0.25 micron CMOS.
In 1994, he joined SNU as an assistant professor in the School of Electrical Engineering
(SoEE), where he is currently a professor.
In 2002, he worked at Stanford University as a visiting professor, on his sabbatical
leave from SNU.
He led the Inter-university Semiconductor Research Center (ISRC) at SNU as the director
from 2008 to 2010.
His current research interests include the design and fabrication of nanoscale CMOS,
flash memories, silicon quantum devices and organic thin film transistors.
He has authored and co-authored over 1000 research papers in journals and conferences.
Prof. Park has served as a committee member on several international conferences including
Microprocesses and Nanotechnology, IEEE International Electron Devices Meeting, International
Conference on Solid State Devices and Materials, and IEEE SiliconNanoelectronics Workshop
and served as an Editor of IEEE Electron Device Letters.
He received “Best Teacher” Award from SoEE in 1997, Doyeon Award for Creative Research
from ISRC in 2003, Haedong Parper Award from the Institude of Electronic Engineers
of Korea (IEEK) in 2015, Educational Award from College of Engineering, SNU, in 2006,
Haedong Research Award from IEEK in 2008, Nano Research Innovation Award from the
Ministry of Science, ICT and Future Planning of Korea in 2013, and Academic Training
Award from Seoul National University in 2015.