1. Intel’s Low Power Technology
With High-K Dielectric
Balapradeep Gadamsetti

2. Why this is required? Continuation of Moore’s Law
Transistor scaling with increased performance and Reduced Power Consumption

3. Introduction
Silicon Industry is scaling SiO2 for the past 15 years and still continuing.
SiO2 is running out of atoms for further scaling but still scaling continues.

4. Now Leakage Power became an Issue !!
What is a Transistor ?
A simple switch
- current flows from source
to drain when gate is at certain
voltage; otherwise it doesn’t flow
Gate dielectrics (SiO2) are only a few atomic layers thick at this thickness even being insulator current leaks through.
Now Leakage Power became an Issue !!

5. Seeking new materials to drive Moore’s Law

6. Replacing SiO2 a challenge?
Materials chosen for replacing SiO2 should be thicker (to reduce leakage power) but should have a “high-K” value.
What is High-K ?
A measure of how much charge a material can hold.
“AIR” is the reference with “K=1”.
"High-k" materials, such as hafnium dioxide (HfO2), zirconium dioxide (ZrO2) and titanium dioxide (TiO2) inherently have a dielectric constant or "k" above 3.9, the "k" of silicon dioxide.

7. Dielectric reduces Leakage power

8. Both the above problems limit the
Problem’s with High-K
Threshold Voltage Pinning- high-K and Polysilicon gate are incompatible due to Fermi level pinning at the High-K and Polysilicon interface which causes high threshold voltages in transistors
Phonon scattering - High-K/ Polysilicon transistors exhibit severely degraded channel mobility due to the coupling of phonon modes in high-K to the inversion channel charge carriers.
Both the above problems limit the
transistor switching speed !!!

9. High-K and PolySi are Incompatible

10. Mobility degradation in High-k\PolySi

11. Phonon Scatterings

12. Challenges with Metal Gates
Solution- Metal Gates
Metal gate electrodes are able to decrease phonon scatterings and reduce the mobility degradation problem.
Challenges with Metal Gates
Requires metal gate electrodes with “CORRECT” work functions on High-K for both nMOS and pMOS transistors for high performance.

13. Work functions for nMOS and pMOS

14. Breakthroughs with Metal Gates
N-Type metal and P-Type metal with the CORRECT work functions on high-K have been engineered.
High-K\metal-gate stack achieves nMOS and pMOS channel mobility close to SiO2's.
High-K\metal-gate stack shows significantly lower gate leakage than SiO2.

15. High-Metal-gate reduces leakage

16. pMOS mobility graph

17. nMOS mobility graph

18. Conclusion
Intel achieved 20 percent improvement in transistor switching speed
Reduced transistor gate leakage by over 10 fold.
Integration of more than 400 million transistors for dual-core processors and more than 800 million for quad-core in Intel® 45nm high-k metal gate silicon technology.

19. References http://www.intel.com/technology/silicon/high-k.htm