The field of the invention is that of forming dual-gate transistors in integrated circuit processing, in particular self-aligned dual gate transistors.
Workers in the field of integrated circuits are constantly striving to reduce the size of devices, in particular transistors.
As FET dimensions are scaled down, it becomes increasingly difficult to control short-channel effects by conventional means. Short-channel effects well known to those skilled in the art are the decrease in threshold voltage Vt, in short-channel devices, i.e. sub-0.1 micron, due to two-dimensional electrostatic charge sharing between the gate and the source/drain region.
An evolution beyond the standard single gate metal oxide semiconductor field effect transistor (MOSFET) is the double-gate MOSFET, in which the device channel is confined between top and bottom gate dielectric layers. This structure, with a symmetrical gate structure, can be scaled to about half of the channel length as compared with a conventional single gate MOSFET structure. It is well known that a dual gate or double-gate MOSFET device has several advantages over conventional single gate MOSFET devices. Specifically, the advantages over conventional single gate counterparts include: a higher transconductance, and improved short-channel effects.
For instance, Monte Carlo simulation has been carried out on a 30 nm channel dual-gate MOSFET device and has shown that the dual gate device has a very high transconductance (2300 mS/nm) and fast switching speeds (1.1 ps for nMOSFET).
Moreover, improved short channel characteristics are obtained down to 20 nm channel length with no doping needed in the channel region. This circumvents the tunneling breakdown, dopant quantization, and dopant depletion problems associated with channel doping that are normally present with single gate MOSFET devices.
Currently, both vertical and horizontal gate structures are actively being pursued by many workers in the field. The horizontal gate structure has several advantages over the vertical structures due to the similarity of current state of the art CMOS devices. However, one major and formidable challenge of fabricating the double gate is aligning the bottom gate to the top gate.
The invention relates to an integrated circuit having dual-gate transistors.
An aspect of the invention is the formation of a self-aligned back gate by oxidizing a portion of the back gate electrode layer using the front gate as an oxidation mask.
Another aspect of the invention is the implantation at the outer edges of the structure of a species that promotes oxidation.
Another aspect of the invention is the oxidation for a sufficient time and temperature to reduce stress in the transistor body.
Another aspect of the invention is the transverse extent of the oxidation to extend the boundary of the back gate below the edge of the transistor body.
Another aspect of the invention is the formation of raised source and drain structures within a space left by the spacers that define the width of the transistor body.
A layer of thermal oxide 3 that will become the back gate dielectric is grown on silicon layer 4 to a thickness of 1 nm to 3 nm and a layer of polycrystalline silicon (poly) 2 is deposited by CVD in the range of 100 nm to 400 nm that will become the back gate electrode. Layer 3 may be composed of oxynitride or may be nitridized as a design choice, so long as it is suitable for a gate dielectric.
Layer 4 is oxidized again with a thermal oxide 5 that will become the front gate dielectric. Layer 5 may also be oxynitride or may be nitridized. It may also optionally be a high dielectric material such as ZrO2, HfO2, AlO2 or other conventional high-k material. Another poly layer 6 is deposited by CVD, preferably in the range of 70 nm to 250 nm in thickness.
The result is that the transistor body has been defined to extend past the first gate electrode on both the left and right in the figure by the thickness of spacers 9 and 10. Spacers 9 and 10 will be referred to as being in proximity to the gate and to the vertical edge of the transistor body, meaning that they are close to the referenced structure but not necessarily directly in contact with it. Additional liners may be deposited as an etch stop or as an insulator to remain in the final structure. The vertical edge of the transistor body is denoted with numeral 11 in this figure and will be contacted by additional silicon added in a later stage. The thickness of the transistor body perpendicular to the plane of the paper will be set according to the designed current capacity of the transistor, as is conventional.
Optionally, an extra space may be allowed in front of or behind the plane of the paper to make contact with the lower gate electrode that will be formed from layer 2.
Illustratively, as shown in
Those skilled in the art would not think to exploit the transverse growth of oxide to penetrate under the transistor body because the expansion in volume of the oxide compared with silicon would have been though to delaminate or to exert undesired stress on the transistor body.
Advantageously, it has been found that the transverse oxide growth is rapid enough in the poly layer 2 that the resulting stress is acceptable. In addition, it has been found that if the oxidation is performed at a temperature of about 1000 C or greater for a time of about 20 min or greater, that the stress caused by the oxidation is relaxed since the SiO2 is more viscous under these conditions.
The parameters of the oxidation step are adjusted empirically to provide for the correct amount of sideways growth. Optionally, an angled ion implant of phosphorus or other oxide-promoting species, indicated schematically by arrows 123 in
Alternatively, or additionally, a nitrogen (or other oxide-retarding species) implant, indicated schematically by arrows 127 and shaded area 128 in
The oxide penetrates a nominal 30-70 nm sideways toward the central portion and a nominal 30-70 nm downward.
After planarization, the oxide is recessed to a height less than the height of the gate stack (and greater than the height of gate 8).
A conventional cleaning step (preferably wet cleaning) removes any residue from vertical surfaces 11 of the transistor body to make a good contact between the body and the raised S/D structures.
Conventional middle of the line and back of the line steps are performed to complete the circuit, referred to for convenience as completing the circuit.
The layers that form gate electrodes 2 and 8 are put down with conventional dopant concentrations (or implanted later) sufficient to provide the proper conductivity for the gates. Similarly, the raised S/D structures have the proper amount of dopant added during deposition.
Layer 4 that forms the transistor body may have a conventional dopant concentration. Those skilled in the art are aware of the type and concentration of dopants to form NFETs and PFETs.
Process Flow
Initial Wafer Preparation
Bond Carrier Wafer
Front Gate Dielectric
Front Gate Electrode
Gate Patterning
First Spacer Formation
Channel Patterning
Second Spacer Formation
Define Self-Aligned Back Gate
Deposit Thick Dielectric, Planarize
Remove First and Second Spacers
Gate Isolation Spacers
S/D Contact Deposition
While the invention has been described in terms of a single preferred embodiment, those skilled in the art will recognize that the invention can be practiced in various versions within the spirit and scope of the following claims.
This application is a continuation of U.S. Ser. No. 11/676,030, filed Feb. 16, 2007, which is a divisional of U.S. Ser. No. 10/663,471, filed Sep. 15, 2003, now U.S. Pat. No. 7,205,185, issued on Apr. 17, 2007.
Number | Date | Country | |
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Parent | 10663471 | Sep 2003 | US |
Child | 11676030 | US |
Number | Date | Country | |
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Parent | 11676030 | Feb 2007 | US |
Child | 12119765 | US |