The present invention relates to a semiconductor tunneling device and particularly to a semiconductor device using band-to-band tunneling (BTBT). More particularly, the present invention relates to a semiconductor transistor device. The present invention also relates to a method for fabricating said device. The present invention further concerns logic circuits or gates comprising the device according to the present invention and a logic scheme implementing logic functions.
The constant scaling of the geometry and the supply voltage used in integrated circuits (IC) is pushing the existing metal-oxide-semiconductor field effect transistor (MOSFET) technology to its limits, especially in terms of the switching slope (SS), which is defined as the derivative of log ID with respect to the gate voltage VGS[1]:
where m is the transistor body factor which depends on the electrostatic control of the channel and n depicts the change in the drain current with respect to changes in the surface potential. It is well known that MOSFETs or any other semiconductor device that relies on thermionic emission of charge carriers is ultimately limited by an SS of 60 mV/dec at room temperature due to the uncompressible limitation of the n factor equation above [2]. As a consequence of this, for a MOSFET device, a gate voltage difference of at least 60 mV is needed to achieve an order of magnitude increase in drain current. This uncompressible SS stands as one of the major problems of modern ICs, due to the fact that circuits cannot have high performance and low standby power consumption at the same time.
To solve this issue, a novel transistor type called Tunnel FETs (TFET) has been proposed. TFETs rely on the peculiar quantum mechanical effect called band-to-band tunneling (BTBT). BTBT effect has been well-known for decades and has been successfully exploited in devices such as the Esaki (tunnel) diodes [3]. The main advantage of the TFET is the demonstrated ability to overcome the 60 mV/dec limitation [4] since it overcomes the n factor limitation stated above for thermionic devices like MOSFET.
However, the efforts to create a TFET structure that is able to compete against the state of the art CMOS technology have met several obstacles. The most pronounced of these problems is the extremely low current levels at ON state, which stems from the fact that device geometry is sub-optimal in maximizing the tunneling rate [5]-[7]. This issue of low ON current necessitates more optimized structures which can offer both the steep transition slope as well as high ON currents.
In order to overcome this difficulty, a novel device architecture called the Electron Hole Bilayer Tunnel FET (EHBTFET) was proposed and studied by the inventors themselves and other scientists in several publications [8]-[12]. The device utilizes the tunneling between electrostatically-induced two-dimensional electron and hole gases (2DEG and 2DHG, respectively). The device architecture consists of a thin semiconductor layer sandwiched between two asymmetrically-placed gate stacks as seen in
Even though the EHBTFET device characteristics are extremely promising, there are several issues with its original implementation which undermine its feasibility. First, the process flow for the integration of such thin semiconductors with asymmetrically placed gates is highly non-trivial. The second issue is scaling; the underlap regions which are required to suppress the leakage current from the source and drain cannot be shrunk below a certain value, which adds additional undesired area in the device layout. Finally, the underlap regions add an extra amount of capacitance which slows the device switching.
The invention is a four terminal semiconductor device (transistor) which utilizes band-to-band tunneling (BTBT) and a novel logic scheme using this device.
The device includes a semiconductor substrate 3 as well as a low bandgap semiconductor 5, such as Indium Arsenide or Indium Antimonide, which sits on the substrate 3. The low bandgap semiconductor 5 is sandwiched between substantially L-shaped n-gate and p-gate dielectric 7, 9 and terminal contacts 11, 15.
The device also includes source 17 and drain 19 regions of opposite conductivity types. BTBT is enabled when the quantized energy levels of the electron and hole gases align.
Since the conduction is dependent on the biasing of both the n-gate 11 and p-gate 15 terminals, the device uniquely combines n-type and p-type transistor behavior and therefore can be used to implement any digital logic function with a significant reduction in transistor count compared to standard CMOS technology.
The above object, features and other advantages of the present invention will be best understood from the following detailed description in conjunction with the accompanying drawings, in which:
a) shows an Electron Hole Bilayer Tunnel FET (EHBTFET) device structure and
a) illustrates a vertical cross sectional view of a device according to the present invention;
b) is a vertical cross sectional view showing the electron and hole inversion layers;
c) is a horizontal cross sectional view of the device of
d) is a horizontal cross sectional view of the device of
e) is a more detailed cross sectional view of the device of
f) is a horizontal cross sectional view of the device of
g) illustrates an exemplary process flow for fabricating the device of
h) is a vertical cross sectional view of a device fabricated according to the process flow of
a) illustrates a circuit schematic symbol for a Pull-Down (similar to NMOS) device according to the present invention where the device conducts only when A=logic-1 B=logic-0;
b) illustrates a circuit schematic symbol for a Pull-Up (similar to PMOS) device according to the present invention where the device also conducts only when A=logic-1 B=logic-0; and
a) shows an inverter;
b) shows a NAND;
c) shows a NOR;
d) shows an XOR;
The invention uses the same conduction mechanism as the EHBTFET, but also contains significant modifications aiming to eliminate or greatly suppress the aforementioned issues.
The invention is a semiconductor device consisting or comprising of four terminals, namely n-gate 11, p-gate 15, source 21 and drain 23 (see
The n-gate 11 and p-gate 15 terminals are used to control the voltage bias on the two gate stacks for the formation of the electron and hole inversion layers 25, 27, respectively (see
The gate stacks consist of or comprise a substantially L-shaped dielectric (SiO2, HfO2 or any other insulator material) layer 7, 9 and gate contact material 11, 15 (metal or any other appropriate alloy). The n-gate and p-gate stack can have the same or different configuration.
The low bandgap semiconductor 5 forms, for example, an elongated fin structure whose cross-sectional view is shown in
A fin structure can be defined for example as a protruding element comprising extending walls and an interconnecting top section. The walls extend outwards from a body (the substrate 3) and are interconnected by the top section at an extremity of the structure. The top section is for example substantially perpendicular to the extending walls. With reference to
With respect to the substrate 3, the low bandgap semiconductor 5 extends substantially perpendicularly outwards from a surface of the substrate 3 to form the fin structure. The fin structure includes substantially vertical or upwardly extending sidewalls, extending from the substrate surface.
The p-gate 15 and the n-gate 11 extend along the first and second sides of the low bandgap semiconductor 5 (sides walls of the fin structure) and define an overlap zone sandwiched between the p-gate 15 and the n-gate 11. A channel of the device is defined by the overlap zone.
The overlap zone can for example extend the full length of the p-gate 15 and/or the n-gate 11.
In one embodiment the overlap zone extends the full length and full height (in the substantially vertical direction of the side walls of the fin structure) of the p-gate 15 or the n-gate 11.
In a preferred embodiment the overlap zone extends the full length and full height (height being in the substantially vertical direction of the side walls of the fin structure) of the p-gate 15 and the n-gate 11 and the device has no under-layer (is under-layer less).
For example, the n-gate 11 and the dielectric layer 7 are mirror symmetrically positioned on the second side of the low bandgap semiconductor 5 with respect to the p-gate 15 and the dielectric layer 9 on the first side of the low bandgap semiconductor 5 (see
The p-gate 15 and the n-gate 11 symmetrically positioned or placed on opposite sides of the low bandgap semiconductor 5. For example, there is no offset between the p-gate 15 and the n-gate 11.
The drain terminal 23 is connected to the n+ doped region 19, which serves as a contact to the n-inversion layer 25 under the presence of an appropriate n-gate voltage. Finally, the source terminal 21 is connected to the p+ doped region 17, which serves as a contact to the p-inversion layer 27 under the presence of an appropriate p-gate voltage.
The spacer regions 31 suppress the direct source-to-drain BTBT conduction. It should be noted that this new structure allows these spacer regions 31 to be much smaller (on the order of 10-20 nm) compared to the EHBTFET described in the previous section and illustrated in
The spacer regions 31 extend in the elongated direction of the low bandgap semiconductor 5.
Table 1 below provides exemplary values for typical dimensions of the principal characteristic features of the device according to the present invention.
The defined directions of ‘width’, ‘height’ and ‘length’ are shown in
By applying an asymmetric bias (in the sense that typically a positive bias is applied to the n-gate whereas typically a negative bias is applied to the p-gate) to the n- and p-gates, as soon as the quantized energy levels of the n- and p-inversion layers 25, 27 align, BTBT allows a steep increase in the device current (illustrated in
a) and (b) provide a representative energy band diagram cut through the low-bandgap region 5 of the device in
A primary advantage of the new device compared to the lateral implementation given in
An exemplary preferred method of fabrication of the device according to the present invention is illustrated in
The first step is the ‘fin-growth’ (fin structure realization) which can be done via two different approaches:
From this point onwards the fabrication steps are the same for both approaches:
Not only the device is easier to integrate on an integrated circuit, but it also intrinsically accounts for hetero-structures, as shown in
The substrate 3 can be chosen to be a convenient large-bandgap material, such as an Indium Gallium Arsenide or Indium Phosphide alloy, that suppresses the leakage current in the substrate. We show (via TCAD simulations) that the invention offers lower OFF currents due to the large-bandgap material used in the substrate 3 and almost the same ON current compared to the lateral implementation of the EHBTFET (see
Furthermore, the use of larger bandgap materials for the substrate region 3 also results in a decreased device capacitance, which in turn reduces the dynamic power consumption of the device. This claim is also supported by TCAD transient simulations (see
The idea of creating electron and hole inversion layers using electrostatics, achieving conduction by inter-layer BTBT can be applied to a variety of different device structures as seen in the device according to the present invention. According to a particular embodiment of the present invention, the same principle is exploited in the case of a substantially cylindrical structure such as a nanowire.
The nanowire semiconductor device comprises of four terminals, n-gate 11, p-gate 15, source 21 and drain 23 (see
The n-gate 11 and p-gate 15 terminals are used to control the voltage bias on the two gate stacks for the formation of the electron and hole inversion layers 25, 27, respectively (see
e) shows a more detailed cross sectional view of the nanowire semiconductor device.
The semiconductor 5 and the p-gate 15 are annular in cross-section and each has the form of an elongated ring. The n-gate 11 has the form of a solid cylinder and is located in the center of the device. The semiconductor 5 encloses the n-gate 11, and the p-gate 15 encloses the semiconductor 5.
The dielectric layer 9 is positioned between the p-gate 15 and the semiconductor 5. The dielectric layer 7 is positioned between the n-gate 11 and the semiconductor 5.
The n+ drain region 19 and the p1 region 17 are both formed in the semiconductor 5 (see
The low bandgap semiconductor 5 forms, for example, an elongated annular fin structure extending substantially perpendicularly outwards from the surface of the substrate 3.
The protruding fin structure can optionally be, for example, encapsulated or enclosed in an insulator material. A portion of the device contacts can for example be left exposed to facilitate electric connection and operation of the device.
BTBT is enabled when the quantized energy levels of the electron and hole gases align.
g) illustrates an exemplary method for fabricating the nanowire semiconductor device of the present invention. The fabrication method is now described.
Table 2 below with reference to
The present invention further concerns logic circuits or gates comprising the above described device according to the present invention and a new logic scheme implementing logic functions.
Another important aspect of the device is its bipolar nature, which has interesting implications in terms of circuit design. The gate metal workfunctions can be chosen such that the device is only conducting when the n-gate input is logic-1 and the p-gate input is logic-0. This configuration is equivalent of having an NMOS and a PMOS in series (but using only a single device) which is also highlighted in the device schematic symbol (see
This new logic scheme allows implementation of logic functions with significant reduction in transistor count. The reduction stems from the fact that a single device of the present invention is able to implement the logic function F=A
Here we present a few of the basic logic standard operation, namely NAND, NOR and XOR (
We verify the proposed logic scheme by simulating the XOR gate in TCAD (see
The new device architecture as described herein can be integrated on advanced Silicon CMOS platforms, which offers an economic advantage. It complements CMOS technology by extending its ability to operate at voltages below 0.5V and will enable an extended design space for digital and analog ICs, with main emphasis on low-power applications.
Having described now the preferred embodiments of this invention, it will be apparent to one of skill in the art that other embodiments incorporating its concept may be used. This invention should not be limited to the disclosed embodiments, but rather should be limited only by the scope of the appended claims.
Number | Date | Country | Kind |
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PCT/IB2014/063389 | Jul 2014 | IB | international |
This application claims the benefit of PCT application No. PCT/IB2014/063389, filed Jul. 24, 2014, the entire contents of which are incorporated herein by reference.