The invention relates to a method of fabricating the gate of a FET and especially to a method of manufacturing a gate of FET with a plurality of different metallic layers.
The intrinsic performance of MOSFETs in terms of current drive, switching power, transconductance and frequency has increased dramatically over several decades. There are a number of developments that have led to these improvements, including for example novel materials, advanced process steps and novel device architectures. One of the most important developments for improving performance has been the reduction in the MOSFET gate length.
However, as the MOSFET gate length shrinks to deep sub-micron length scales, much less than 1 μm in length, intrinsic device performance degrades for a number of reasons, collectively known as short-channel effects. One effect is drain induced barrier lowering (DIBL) which occurs as the channel length becomes comparable to the channel depth. In this case, the gate gradually loses the control over the channel to the drain so when the drain voltage changes this results in a change in the threshold voltage. A second effect is that hot carriers accelerated by high electric fields cause impact ionization. A third effect is that the pinch-off position moves towards the source at high drain bias. This means that the channel length varies with drain bias resulting in a finite output conductance.
A further short-channel effect is gate transport efficiency. Charge carriers overcome a potential barrier near the source and are injected into channel with low velocity. They are then accelerated towards the drain. The current is however largely determined by the low velocity at the potential barrier near the source.
A number of novel architectures using a thin silicon body have been proposed for use after the 65 nm roadmap node published by the International Technology Roadmap for Semiconductors (ITRS). These architectures include fully depleted silicon on insulator (FDSOI) or dual gate FinFETS. However, neither of these approaches address the gate transport efficiency.
A theoretical approach to this problem was proposed in M Shur, “Split gate field effect transistor”, Appl. Phys. Lett volume 54 (1989) page 162, which demonstrated theoretically that a MOSFET with a longitudinally varying threshold voltage (along the gate length) has improved gate transport properties. The proposed practical implementation was a FET with a split gate, the gate over the drain end of the channel having a positive bias offset, for the NMOS case. The effective gate overdrive (or swing), i.e. the applied voltage minus the threshold voltage, is hence less at the source end. This in turn results in a higher resistance at the source end which in turn leads to higher longitudinal electric fields at the source end. These higher fields increase the acceleration of charges at the source increasing the average velocity and hence the current.
This split-gate structure is however not practicable to manufacture. Another structure was proposed by Long et al, in “Dual material gate (DMG) field effect transistor”, IEEE transactions on electronic devices, volume 46 (1999) page 865. This uses a gate made of two diff erent metallic layers with different work functions along the length of the channel. In particular, for NMOS, the metallic layer gate above the source end of the channel has a higher work function resulting in a higher threshold voltage, hence lower gate overdrive, than the metallic layer gate above the drain end of the channel. For PMOS, the metallic layer gate above the source end should have a lower work function.
Long et al even manufactured a device with a 1 μm length, using tilt evaporation.
However, as far as the present inventors are aware, no scalable manufacturing methods capable of producing such longitudinally varying gate voltages even at very short gate lengths less than 100 nm has been proposed.
Accordingly, there remains a need for a suitable manufacturing process and scaled devices manufactured in accordance with the process.
According to the invention there is provided a method according to claim 1.
By defining the metallic layers on the sides of a dummy structure, very short gate length transistors may be manufactured with multiple gate metallic layers with different work functions.
Note that the term “metallic layer” as used in the present application includes layers of metals, conductive semiconductors such as doped polysilicon, as well as materials such as silicides and nitrides where these conduct.
Embodiments of the invention will now be described, purely by way of example, with reference to the accompanying drawings, in which:
The Figures are schematic and not to scale. In particular the vertical dimension of the side views is exaggerated for clarity.
A method according to a first embodiment of the invention will be described with reference to
Referring to
A dummy structure 8 is then formed above the gate dielectric by deposition of a layer of material, lithography to define dummy structure region 9 and etching. In the example, the dummy structure is formed of a 100 nm thick layer of polysilicon. This results in the structure of
As illustrated in
The next step is to anisotropically etch back the first metallic layer 16 to remove it from the top 12 of the dummy structure 8 and the top of the gate dielectric 6 while leaving a first metallic layer region 16 on the sides 10 of the dummy structure as illustrated in
Next, the deposition and etch back processes of
The dummy structure 8 is then removed by a selective etch and processing continues, by implanting forming low doped source 22 and drain 24 regions as illustrated in
Thus, as illustrated in
The longitudinal (length) direction of the transistors is illustrated by arrow 30 in
The method thus provides a way of making transistors with different work functions to reduce short gate length effects even with very short gate lengths in the range below 100 nm, since the length of the gate is determined by the thickness of metallic layers deposited for example by atomic layer deposition which may be accurately controlled.
With suitable choices of gate metallic layers, short channel effects will be suppressed and transport efficiency properties enhanced.
Note that in the embodiment shown a trench isolation structure 4 extends through the centre of the dummy structure region 9 and hence isolates the two transistors from each other.
In alternate embodiments (not shown) this isolation is omitted which means that the two drain regions 24 are connected to one another since there is a single implantation in the dummy structure region 9. Thus, in this case the transistors have a common drain. A common source can be provided in a similar fashion by forming the source regions 22 in common in the dummy structure region. Pairs of transistors with a common source or drain occur frequently in standard cell designs, and the embodiments provide a convenient approach to delivering them.
Then, as illustrated in
Thus, the second embodiment has the advantage that there is no need to etch away metallic layers 16, 18, 20 in regions 28 as in the first embodiment, saving the need for one mask and one etch step.
The invention delivers a varying threshold voltage along the length of the gate. In alternative arrangements, the metallic layer adjacent to the source and drain may be the same and a different metallic layer with a different work function provided in the central part of the gate over the central part of the channel. This provides a different set of properties.
Those skilled in the art will realise that many variations may be made to the transistors illustrated and indeed that the transistors may be included in many different processes.
Number | Date | Country | Kind |
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06123538 | Nov 2006 | EP | regional |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/IB2007/054350 | 10/25/2007 | WO | 00 | 5/5/2009 |
Publishing Document | Publishing Date | Country | Kind |
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WO2008/056289 | 5/15/2008 | WO | A |
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