II. DEVICE FABRICATION
Fig. 1(a) and Fig. 1(b) show an optical microscopic image and a schematic cross-sectional view of our proposed
CTM-TFT with DG configuration employing the oxide semiconductor channel and charge
trap layer (CTL). First, indium-tin-oxide (ITO)-coated glass substrate was patterned
into the bottom gate (BG) electrodes. Al2O3 thin films were then formed at 200 ℃ as bottom gate insulators (BGI) via atomic layer
deposition (ALD), where trimethylaluminium [TMA, (CH3)3Al] and water vapor (H2O) were used as the aluminum and oxygen precursors, respectively. The film thicknesses
of the BGIs were controlled during the film formation; BGIs of 100 and 50 nm thicknesses
were fabricated in order to examine the effect of BGI thickness on memory device operations.
150-nm-thick ITO thin films were deposited by DC sputtering and patterned for the
formation of source/drain (S/D) electrodes. Prior to performing the patterning process
for the S/D electrodes, a thermal treatment was performed at 250 ℃ in a vacuum to
control the film crystallinity and electrical conductivity of the sputtered ITO film.
Then, 20-nm-thick IGZO active channel layers were formed using RF magnetron sputtering
with a single IGZO (In:Ga:Zn=2:1:2) target at room temperature (RT). Al2O3 (5 nm) was formed as the first tunneling layer by ALD at 180 ℃. After the patterning
process of the IGZO channel and the first tunneling layers, 5-nm Al2O3, 30-nm ZnO, and 3-nm Al2O3 layers were successively deposited by ALD at 200, 100, and 150 ℃ as the second tunneling,
charge-trap, and top-protection layer, respectively. The deposition processes were
all performed in the same chamber without removing a vacuum in order to ensure higher
qualities of the interfaces between the layers. The use of a ZnO CTL was one of the
main features for our proposed DG CTM-TFTs. The double-layered tunneling layer and
top-protection layers were strategically designed to prevent damage induced to the
IGZO channel from wet-etching during the CTL patterning process and to protect the
surface of the ZnO CTL during the lithography process, respectively[16]. After the trilayered structure was patterned using one-step wetetching process with
diluted hydrofluoric acid (HF:H2O=1:200), 50-nm-thick Al2O3 thin films were formed as top gate insulators (TGI) by ALD at 150 ℃. The contact
holes to electrically connect the S/D electrodes with probing pads were formed by
opening through the blocking oxide with phosphoric acid at 120 ℃. Finally, a 150-nm-thick
ITO top gate (TG) electrode was deposited using DC sputtering at RT and patterned
via a lift-off process to minimize the chemical damage to the layers underneath. For
convenience, the DG CTMTFTs using the BGIs with thicknesses of 100 and 50 nm were
termed as Dev. 1 and Dev. 2, respectively.
Fig. 1. (a) Optical microscopic image, (b) schematic crosssectional view of the fabricated
CTM-TFT with DG configuration.
Device characteristics were evaluated using a semiconductor parameter analyzer (Keithley
4200) and a pulse generator (HP 8110A) in a dark box at RT. At SG mode operations,
only three terminals were used, correspond to the source, drain, and TG electrodes.
The BG was oated when the electrical characteristics of the TG device were measured.
On the other hand, for the DG mode operations, four terminals corresponding to source,
drain, TG, and BG electrodes were used, in which both gate electrodes (TG and BG)
were connected, and the transfer characteristics were measured with DG configuration[18]. The BG electrode was also utilized for introducing the fixed bias in order to examine
the effect of fixed voltage at BG ($V_{BG}$) on the device characteristics. In the
evaluations of the memory operations, P/E voltage pulses were applied to the TG ($V_{TG}$),
and the drain voltage ($V_{DS}$) was set as 0.1 V. The read-out operations were measured
at a $V_{TG}$ of 0 V with a given amplitude of the fixed $V_{BG}$. For our proposed
CTM-TFTs, the memory off- and on-states could be stored with the program and erase
operations, respectively.
III. MEMORY DEVICE CHARACTERIZATION
Fig. 2(a) shows the transfer characteristics for Dev. 1 at a $V_{DS}$ of 0.1 V and compares
them with those obtained after the repeated P/E operations using pulse signals, in
which ±20-V pulses with 1-s duration were repeatedly applied with 103 cycles. For the DG mode operation, the gate voltage was applied to both electrodes
of the TG and BG and was incrementally varied from -20 V to 20 V in both the forward
and reverse directions. Clear clockwise hysteretic behavior in the transfer curves
were observed because the turn-on voltage ($V_{on}$) was shifted due to charge-trap
and detrap operations. The MW, which was defined as the width of the hysteresis in
the transfer curve, was 13.8 V. The hysteresis in $I_{D}$-$V_{GS}$ curve can also
originated from the undesirable charge-injection into the interface trap states as
well as the designed chargetrap/de-trap events during the P/E operations. However,
the obtained transfer characteristics and the MW supported by the charge-trap mechanism
were already found to be very stable in our previous publications [8,16,23]. The width and location of the MW are important device parameters for CTM-TFTs because
they determine operating conditions, such as the P/E and readout voltages. The MW
obtained for Dev. 1 was located near at 0 V as the center in x-axis. It is highly
desirable for the CTM-TFTs to read-out the programmed memory states close to 0 V for
the purpose of symmetrically choosing the P/E voltages and effectively avoiding the
additional field effects during the read-out operations. Furthermore, the MW and transfer
characteristics did not show any remarkable changes even after the repetition of the
P/E operations, which suggests that the evaluated device does not experience undesirable
variations in basic memory characteristics during P/E operations. Otherwise, numerical
analyses for the programmed current values obtained for the P/E operations could not
be guaranteed. Concerning the high-temperature transfer characteristics and retention
characteristics of the CTMTFTs with the same gate-stack structure, stable operations
were previously confirmed[19]. The photoresponses of the fabricated CTM-TFTs were also examined at various wavelength
of light sources. Even under the light-illumination conditions, the memory device
operations including the MW and program speed exhibited good memory characteristics
and did not exhibit any specified dependence of wavelength[20].
Fig. 2(b) shows the P/E characteristic for the same device when the pulse width of the P/E
voltages were varied from 1 s to 1 μs. For this experiment, the amplitude of P/E voltage
and $V_{DS}$ were set as ± 20 V and 0.1 V, respectively; the programed currents were
readout at 0 V; the memory on/off ratio was defined as the current ratio between the
on- and off-programmed states at the given read-out conditions. While measuring the
memory operations, the BG electrode was grounded. Since the on- and off-programmed
currents provide meaningful information on nonvolatile memory behavior of the fabricated
CTM-TFTs, the P/E characteristics were evaluated using the memory on/off ratio rather
than shifts in the $V_{TH}$. In other words, (1) the absolute levels of the on- and
off-programmed currents and their variations with respect to changes in the P/E and
read-out conditions practically reflect the program performance of the transistor-type
memory device, and (2) the current ratio between the programed states at given read-out
conditions can be helpful in creating a practical design for the memory applications.
In practical applications, the modulations in channel conductance can be important
to operate given circuits and/or systems embedded with the proposed CTM-TFTs, even
though it is the case that the $V_{TH}$ is more sensitive to the changes in the number
of trapped charges. The maximum memory on/off ratio was obtained as 5.8×106 when the P/E pulse duration was 1 s. The $I_{D}$ value (3.6×10-7 A) of the on-state programmed with a 1-s-duration and +20-V-amplitude pulse was obtained
to be almost the same as the $I_{D}$ value (6.1×10-7 A) of the on-state at a $V_{R}$ of 0 V from the transfer characteristics obtained
in Fig. 2(a). Even though the memory on/off ratio showed a tendency to decrease as the P/E voltage
pulse duration decreased, a memory on/off ratio as high as 1.5×105 was measured at a pulse duration of 10 μs. Furthermore, another noteworthy characteristic
was observed in the device; the nonvolatile memory operations could be confirmed to
be available even at a pulse duration of 1 μs. As shown in Fig. 2(a), we can say that the variations in the programmed currents accurately reflected the
program speed characteristics of the evaluated memory TFT, considering that there
were no remarkable variations between the initial and post-P/E transfer curves. Thus,
the fabricated DG CTM-TFTs were confirmed operate well at high speeds as nonvolatile
memory elements. The P/E speed is closely related to the charge-trap and detrap efficiency
for the CTM-TFTs. As illustrated in Fig. 2(b), the off-state was more vulnerable to the erase operations with a shorter pulse duration
compared to the on-state. The P/E characteristics could be remarkably varied with
the voltage condition of read-out operations ($V_{R}$) and the location of the MW.
Read-out operations performed at a $V_{R}$ that deviated from 0 V could deteriorate
the P/E performance, especially for one of the memory states (on- or off-states),
due to undesirable field applications into the gate stack. From these viewpoints,
the DG configuration has beneficial effects for accurately controlling the memory
performance of the CTM-TFTs because the back-channel potential and the MW location
could be strategically controlled by adjusting the suitable $V_{BG}$.
Fig. 2. (a) Drain current – gate voltage transfer characteristics and gate leakage
currents of Dev. 1 at the DG mode operation, in which the gate voltage was simultaneously
applied to TG and BG. The measurements were repeated after the number of P/E operations,
(b) Variations in programmed currents during the P/E operations as a function of P/E
voltage pulse width.
The ability to have control over the $V_{TH}$ is one of the most important features
expected for the DG TFTs. Fig. 3(a) and Fig. 3(b) show the variations in the transfer characteristics for each device when the fixed
$V_{BG}$ was varied to 5, 0, -5, -10, and -15 V. The $V_{GS}$ was swept in the same
ranges from -20 to 20 V for each measurement to demonstrate the $V_{TH}$ controllability.
As expected, when the negative and positive biases were fixed at the BGs, the values
of $V_{TH}$ for both devices were clearly modulated in positive and negative directions
in the $V_{GS}$ axis, respectively. Even though the values of $V_{on}$ (and $V_{TH}$)
and the location of the MW can also be controlled via the electronic nature of the
IGZO active channel, the application of a fixed $V_{BG}$ can be effectively exploited
as one of the benefits of the DG configuration, because the location and width of
the MW can be intrinsically determined by the charge-trap/detrap events during the
memory operations. These $V_{TH}$ modulations can be generally explained by the accumulation-depletion
transitions within the IGZO active channels, which were controlled by the amplitudes
and polarities of the $V_{BG}$ biases[3,10,12]. The channel layer could be easily formed using a smaller $V_{TG}$ with the application
of a positive $V_{BG}$; hence, the TFT was turned on at a lower $V_{TH}$. On the other
hand, for the application of a negative $V_{BG}$, a larger $V_{TG}$ was required to
form the conductive channel, owing to the formation of a depletion layer near the
BGI interface region. In the negative $V_{BG}$ case, the TFT was eventually turned
on, but at a higher $V_{TH}$. For further clarification of the $V_{TH}$ characteristics,
the effect of different BGI thicknesses were examined. When the BGI thickness was
reduced from 100 (Dev. 1) to 50 nm (Dev. 2), the field effect induced by the $V_{BG}$
is expected to result in increased sensitivity. Therefore, a decrease in the BGI thickness
should be able to improve the $V_{TH}$ tunability. However, current drivability is
limited at strong negative $V_{BG}$ conditions due to the formation of full-depletion
in the active channel, as illustrated in Fig. 3(b). The $V_{TH}$ tunability can be explained by the capacitance coupling ratio of $C_{BGI}$/$C_{TGI}$,
in which $C_{BGI}$ and $C_{TGI}$ correspond to the capacitance per unit area of the
BGI and TGI, respectively. Assuming that the $C_{dep}$, or the capacitance per unit
area of depletion layer within the active channel, is much larger than the $C_{BGI}$
and $C_{TGI}$, the $V_{TH}$ of the TG device can be determined as follows:
Fig. 3. Sets of transfer characteristics of the (a) Dev. 1, (b) Dev. 2 when the fixed
$V_{BG}$ was controlled to 5, 0, -5, -10, and -15 V, respectively.
where $V_{TT0}$ and $V_{BT0}$ correspond to the threshold voltages when the top and
bottom gates were employed for the SG mode operations, respectively[21]. The threshold voltage of the device with TG configuration at a fixed $V_{BG}$ bias
is directly related to the capacitance coupling ratio of $C_{BGI}$/$C_{TGI}$. Thus,
the $V_{TH}$ tunability of Dev. 2 should be enhanced compared to that of Dev. 1. Consequently,
the coupling ratio of $C_{BGI}$/$C_{TGI}$ should be carefully designed such that a
compromise is reached for the characteristics of $V_{TH}$ tunability and current drivability
in the DG CTM-TFTs. The ability to control the $V_{TH}$ with DG configurations in
CTM-TFTs can enhance the program performance by easily allowing suitable value of
$V_{R}$ for the DG CTM-TFT to be set, which is one of the most important benefits
supported by the DG configuration for CTM-TFT applications over the conventional SG
configuration[22].
The effects of the fixed $V_{BG}$ on the memory operations were examined in detail
for the fabricated DG CTMTFTs. Fig. 4(a) shows the P/E operation speeds for the fabricated devices as a function of the applied
$V_{BG}$, where the P/E speed was defined as the voltage pulse width when the memory
on/off ratio exceeded 3-ordersof magnitude for conveniences in evaluating the effects
of applied fixed $V_{BG}$ on the P/E characteristics of the proposed CTM-TFTs with
DG configuration. The applied voltages for the P/E operations were set at ± 20 V.
The P/E speed was found to be remarkably enhanced as the $V_{BG}$ decreased. When
the $V_{BG}$ was set at -3 V, the P/E speeds for Dev. 1 and Dev. 2 were estimated
to be approximately 10 and 1 μs, respectively. However, the P/E speeds for both devices
slowed down to longer than 1 s when the $V_{BG}$ was set at 3 V. Generally speaking,
the $V_{R}$ should be changed depending on the threshold voltage and the location
of MW. Thus, the P/E speeds can be mainly controlled by the charge-trap and detrap
efficiencies for the CTM-TFTs fabricated with given gate-stack structures. Thus, it
can be the case that the P/E speeds are not directly related to the $V_{R}$ conditions.
However, the memory P/E operations of the proposed CTM-TFTs are also influenced by
the P/E and $V_{BG}$ conditions. Furthermore, the read-out operations can desirable
to be performed at a $V_{GS}$ of 0 V from the viewpoints of the removal of unexpected
internal field as well as simple set-up’s for memory operations. Therefore, the width
of MW and its location are eventually important to determine and improve the P/E speeds
of the proposed CTM-TFTs. In other words, when the fixed $V_{BG}$ with a suitable
bias was not introduced, the on- and off-memory states of the CTM-TFTs could not be
readout at the same $V_{R}$. As discussed in Fig. 3, the $V_{TH}$ tunability is a strong benefit supported by the DG configuration. Consequently,
the DG configuration can be a simple but effective method to solve the problem of
the CTM-TFTs with SG configuration. Thus, for the memory array composed of DG CTM-TFTs,
we have much more degree of freedom in designing the memory array operation scheme,
because the MW locations can also be controlled for the array structure.
Fig. 4(b) shows the variations in the memory on/off ratios for Dev. 1 and Dev. 2 when the widths
of P/E voltages were fixed at 100 μs. The P/E voltages were set at ± 20 V and the
$V_{BG}$ was varied between -3, 0, and 3 V. The memory on/off ratio obtained while
using a $V_{BG}$ of - 3 V was higher than 5-orders-of magnitude for both devices;
however, the devices did not exhibit nonvolatile memory operations at a $V_{BG}$ of
3 V. These results suggest that the fixed $V_{BG}$ bias plays critical roles in guaranteeing
the high performance of the memory characteristics for the fabricated DG CTM-TFT devices.
Similarly, the optimum $V_{BG}$ conditions were examined to maximize the memory on/off
ratio for Dev. 1 and Dev. 2, as shown in Fig. 4(c) and Fig. 4(d), respectively. For the device using the BGI with a thickness of 100 nm, the P/E operations
could be completely performed at a $V_{BG}$ of -3 V, and a maximum memory on/off ratio
could be obtained due to appropriate control in the locations of the MWs and the read-out
condition at a $V_{R}$ of 0 V. On the other hand, when the $V_{BG}$ decreased to -10
V, the on-currents obtained by erase operations were observed to sharply decrease,
owing to the excessive formation of a depletion region within the active channel.
For the device using a BGI with a thickness of 50 nm, the maximum on/off ratio could
also be obtained at a $V_{BG}$ of -3 V. However, we found that the erase operation
could not be performed, even when using a $V_{BG}$ of -5 V. In other words, our results
suggest that the effects of the fixed $V_{BG}$ could be improved by reducing the BGI
thickness. However, the memory device performance improvements, including higher memory
on/off ratios and P/E speed, were not impressive for the device with a BGI thickness
of 50 nm. Consequently, in order to effectively benefit from effects of using a fixed
$V_{BG}$ for the DG CTM-TFTs, the BGI thickness must be carefully optimized, considering
the fact that a significant decrease in the BGI thickness can deplete the active channel,
even when using a smaller $V_{BG}$ due to higher field sensitivity.
Fig. 4. (a) Variations in the P/E speed, (b) the memory on/off ratio for Dev. 1 and
Dev. 2 as a function of fixed $V_{BG}$ bias. The P/E voltages were set as ±20 V. For
comparisons, the drain currents programmed by P/E operations were examined for the
(c) Dev. 1, (d) Dev. 2, respectively, in which P/E voltage pulse width was fixed at
100 μs.
For the nonvolatile memory operations using our proposed DG CTM-TFTs, it was important
to investigate the feasibility of reducing the P/E voltages for the lowvoltage operations
by appropriately choosing the $V_{BG}$ bias conditions. Changes in the memory on/off
ratios for Dev. 1 and Dev. 2 as a function of P/E voltage when the fixed $V_{BG}$
was varied to 3, 0, and -3 V are shown in Fig. 5(a) and Fig. 5(b), respectively. The duration of the voltage pulses for the P/E operations were set
at 1 s. When the $V_{BG}$ bias was fixed at 3 V, the obtained memory on/off ratios
were lower than 10 and significantly decreased with decreasing the P/E voltages. Furthermore,
even when the $V_{BG}$ bias was fixed at 0 V, the memory on/off ratio obtained at
a P/E voltage of ± 20 V drastically decreased to be only 100 for both devices as the
P/E voltage decreased. On the other hand, it was noteworthy that the memory on/off
ratio of Dev. 1 was observed to be as high as 106, even with the P/E voltage of ±15 V at a fixed $V_{BG}$ bias of -3 V (Fig. 5(a)). For Dev. 2, an on/off ratio higher than 104 was obtained using the same conditions (Fig. 5(b)). These results clearly suggest that the P/E voltages could be remarkably reduced
for the proposed DG CTM-TFTs by selecting suitable fixed $V_{BG}$ bias conditions.
For both devices, the memory on/off ratios were improved by decreasing the $V_{BG}$
bias from 3 to -3 V. It is interesting to note that even with a P/E voltage of ±15
V, the memory on/off ratio of Dev. 1 could be pushed as high as 3.1×106. Similarly, the memory on/off ratio of Dev. 1 also did not experience any notable
degradation, while the on/off ratio of Dev. 2 remarkably decreased by decreasing the
P/E voltage. Consequently, the BGI thickness was also found to be a critical design
parameter from the viewpoint of lowvoltage operation. Dev. 1, using the BGI with a
thickness of 100 nm, was evaluated to be more effective at reducing the P/E voltages
compared to Dev. 2 with a BGI thickness of 50 nm. As discussed in Fig. 4, while a $V_{BG}$ of -3 V was at an optimum condition to maximize the on/off ratio
for Dev. 1, the memory off-state for Dev. 2 could not be fully programmed at a $V_{BG}$
of -3 V due to higher field sensitivity. These effects were more remarkably reflected
through changes in the device characteristics (e.g. by decreasing the P/E voltages).
Thus, the reduction margin in P/E voltages for Dev. 2 with a thinner BGI thickness
became smaller than those for Dev. 1 with a thicker BGI. These observations suggest
that our proposed DG CTM-TFTs could be operated using lower P/E voltages by adjusting
the optimum operation conditions in order to effectively reduce the power consumption.
Fig. 5. Variations in the memory on/off ratio for the (a) Dev. 1, (b) Dev. 2 as a
function of P/E voltages when the fixed $V_{BG}$ was modulated to -3, 0, and 3 V,
respectively. The P/E voltage pulse width was fixed at 1 s.
The memory retention characteristics were evaluated for the DG CTM-TFTs (not shown
here). The fixed $V_{BG}$ bias was simultaneously applied during the P/E and readout
operations; however, during the retention period, the fixed $V_{BG}$ was removed from
the gate terminal. The memory retention time, especially for the off-current, was
improved when the negative fixed $V_{BG}$ bias was introduced. Contrarily, when the
positive fixed $V_{BG}$ was applied, the memory on/off ratio drastically decreased
due to the increase in off-current with a lapse of retention time. These results provide
evidence that the retention characteristics of the DG CTM-TFTs could be sensitive
response to the fixed $V_{BG}$ bias conditions. For example, we observed that the
memory off-current state deteriorated in time, even at a small positive $V_{BG}$ value.
As discussed previously, during the program and readout operations, the location of
the MW is important, as it promotes stable off-current levels. Therefore, the offcurrent
programmed at a negative fixed $V_{BG}$ (-3 V in this work) also exhibited more reliable
behavior, with a lapse of retention time, than the off-current programmed at a positive
fixed $V_{BG}$. Furthermore, the memory off-current programmed at a positive fixed
$V_{BG}$ might show the increasing trend with a lapse of retention time. Ideally,
the trapped charge should be stably located within the CTL and the off-programmed
current should keep its value with time evolution. However, the trapped charge can
be gradually de-trapped from the CTL and/or overlap regions of S/D and active layers
and then the $V_{TH}$ is gradually returned because of unstable program event at a
positive fixed $V_{BG}$. Intrinsically, the retention performance is to be determined
by the charge-trap efficiency into the ZnO CTL. On the other hand, for the DG CTM-TFTs,
the retention time can be improved by using strategies supported by the device design:
(1) the optimum read-out condition (around at 0 V) can be determined by tuning the
location of the MW for the DG configuration, and (2) the fourth terminal of the DG
configuration provides a meaningful degree of freedom for memory operations. In other
words, the effect of fixed $V_{BG}$ bias can be controlled by appropriately designing
the capacitance coupling ratio between the bottom and top gate insulators, which was
designed by varying the BGI thickness in this work. Consequently, the memory retention
time can be remarkably influenced by suitably controlling the fixed $V_{BG}$ condition
when using the DG configuration. Although the test time was only long enough for a
comparison between the two test conditions, the memory retention time of the proposed
DG CTM-TFTs could be expected to be far longer than 103 s and to satisfy the given requirements for NVM operations.
Finally, our characterization experiments allowed us to determine the device operation
mechanisms for our proposed DG CTM-TFTs. When the $V_{BG}$ is grounded, the device
operations were found to be mainly influenced by the $V_{TG}$, similar to SG configuration.
The basic operations of the CTM-TFTs with SG configuration was extensively discussed
in our previous publication[23]. For the program operation of off- states, the positive $V_{TG}$ is introduced, and
hence, the electrons accumulated within the IGZO channel are injected and trapped
into the ZnO CTL. Then the $V_{TH}$ is shifted to the positive direction. Although
the charge trap/de-trap events for the electrons are supposed to be dominated by the
Fowler-Nordheim (F-N) tunneling, the areal geometry effects of a ZnO CTL should also
be considered as one of the process-dependent parameters influencing on the device
characteristics of the CTM-TFTs[24]. The device with a larger overlapped region between the CTL and active channel exhibited
a larger MW and faster program speed, which could be explained by modulations in the
number of trap sites within the ZnO CTL and the field concentration at the edge area
of the overlapped region.
On the other hand, for the CTM-TFTs with DG configuration, when a negative $V_{BG}$
is introduced, electrons in the active layer accumulate at the interface near the
tunneling layer due to the formation of depletion region at the interface between
the IGZO and BGI. Thus, the MW can be shifted at an application of appropriate fixed
$V_{BG}$. This relationship explains that more stable P/E operations could be obtained
with the application of a larger negative $V_{BG}$, as discussed in Fig. 3 and Fig. 4. However, when an excessively large $V_{BG}$ is applied, the IGZO channel is fully
depleted; therefore, the P/E characteristics deteriorate. In a similar fashion, when
a positive $V_{BG}$ is introduced, the number of electrons, which can be trapped into
the CTL via F-N tunneling, significantly decrease near the tunneling layer due to
the electron accumulation at the interface between the IGZO and BGI. As a result,
the memory off-state cannot be stable and the observed current level becomes relatively
high. Therefore, it would be difficult to guarantee quality performance of the P/E
characteristics under positive $V_{BG}$ conditions, even when the same P/E voltages
are applied during the P/E operations with suitable control over the $V_{R}$. These
observations can be one of the main reasons why the nonvolatile memory operations
of the DG CTMTFTs were degraded during the application of a positive $V_{BG}$. The
fixed $V_{BG}$ conditions required for the formation of fully-depleted regions can
be modulated by the BGI thickness. As such, the BGI thickness control can be concluded
as one of the most important design parameters for the improvements in device characteristics
of the proposed DG CTM-TFTs. Actually, considering the device design parameters such
as thickness values of tunneling and blocking oxides, the memory operation behaviors
cannot be suitably explained by the F-N tunneling mechanism. Thus, it would be more
desirable to quantitatively analyze the operation mechanism for the proposed DG CTM-TFTs
by means of numerical simulations including the processand device structure-dependent
parameters as future works.