Analysis of Mechanical Stress Effects in Short Channel MOSFETs

1. Analysis of Mechanical Stress Effects in Short Channel MOSFETs C. Gallon1, G. Reimbold1, G. Ghibaudo2, R.A. Bianchi3 and R. Gwoziecki1,3. 1CEA-Leti, 38054 Grenoble Cedex 9, France. Tel. : +33 (0)4 38 78 49 93. E-mail: cgallon@cea.fr 2IMEP, BP257, 38016 Grenoble Cedex 9, France. 3STMicroelectronics, Central R&D, 38921 Crolles, France. ULIS 2003 - Udine (Italy) - C. Gallon

2. OUTLINE • Introduction • Experimental Method • Four point bending technique • Tested devices • Experimental Results: • Stress Influence on Long Channel Devices • Stress Influence on Short Channel Devices • Conclusion and Perspectives ULIS 2003 - Udine (Italy) - C. Gallon

3. INTRODUCTION (1) • Context: • Generation of mechanical stress at various process steps. • These effects are more important in scaled CMOS devices • A key role of mechanical stress in MOSFETs devices: • Performance improvements (SiGe, SiGe:C… ) • or Performance reductions (STI,…) • Needs: • Improve extraction methodologies versus mechanical stress. • Better understanding and evaluation of stress effects on MOSFETs devices. ULIS 2003 - Udine (Italy) - C. Gallon

4. INTRODUCTION (2) • Purpose of this work: • Analysis of external mechanical stress effects on MOSFETs from advanced 0.13µm CMOS technology: • Relative variations of mobility with external stress, • Extraction of Piezoresistive Response (PR), • Simple approach proposed to extract PR on short devices accounting for Rsd influence. • Objectives: Try to provide data for device simulators and a betteranalysis of stress effects. ULIS 2003 - Udine (Italy) - C. Gallon

5. F F a 2a a EXPERIMENTAL METHOD: 4-POINT BENDING • Principle of a four-point bending technique: • Interest: Application of an uniform uniaxial stress between the two central fulcrums. ULIS 2003 - Udine (Italy) - C. Gallon

6. F F a 2a a ydis EXPERIMENTAL METHOD: 4-POINT BENDING • Evaluation of stress : • Estimated error: - Uncertainty on L, a , y measurements and mainly on E value. - Global accuracy: 7% ULIS 2003 - Udine (Italy) - C. Gallon

7. compressive L 2a a a tensile L Micrometer screw a a 2a EXPERIMENTAL METHOD: 4-POINT BENDING ULIS 2003 - Udine (Italy) - C. Gallon

8. EXPERIMENTAL METHOD: 4-POINT BENDING • Specific characteristics: • Rectangular strip are cut from a saw technique. • With an appropriate preparation of the strips, mechanical stress: • longitudinal direction (// to current flow) • or transversal direction ( to current flow). • Most strips fail for 150-200MPa • Keep the applied mechanical stress below 100MPa. ULIS 2003 - Udine (Italy) - C. Gallon

9. Gate Gate Source Drain Source Drain Buried oxide Substrate Substrate Bulk Technology SOI technology DEVICES TESTED ON 4-POINT BENDING • Bulk and SOI similar technologies - nMOS and pMOS fabricated on (100) substrates - Tox=2nm; W=10µm;Long (L=10µm) or short (L=0.13µm) channel length; - Important point on our short devices: a long distance between STI and gate  limit parasitic internal stress. - Mechanical stress ranging from 0 to 100MPa was applied. ULIS 2003 - Udine (Italy) - C. Gallon

10. 5 5 Id@100MPa Id@100MPa 4 4 S) S) 3 3 5 5 - - Id@0MPa Id@0MPa (10 (10 2 2 Gm Gm 1 1 0 0 - - 0,5 0,5 0 0 0,5 0,5 1 1 1,5 1,5 Vg Vg (V) (V) EXPERIMENTAL RESULTS: Long Channel Devices • Effects of mechanical stress on transfer characteristics - Linear region characteristics of nMOS BULK: - Use of standard expressionsto extract VTand µ. - Note the invariance of VTand mobility variations. ULIS 2003 - Udine (Italy) - C. Gallon

11. 8 8 8 8 8 8 8 8 nMOS pMOS 7 7 7 7 6 6 6 6 SOI SOI L=10µm W=10µm L=10µm W=10µm 4 4 4 4 6 6 6 6 BULK 2 2 2 2 5 5 5 5 BULK µ/µ (%) Longitudinal µ/µ (%) 0 0 0 0 Transversal 4 4 4 4 -2 SOI 3 3 3 3 -4 BULK 2 2 2 2 BULK -6 Longitudinal 1 1 1 1 -8 SOI Transversal 0 0 0 0 0 0 0 0 25 25 25 25 50 50 50 50 75 75 75 75 100 100 100 100 0 0 0 0 25 25 25 25 50 50 50 50 75 75 75 75 100 100 100 100 Tensile Stress (MPa) Tensile Stress (MPa) EXPERIMENTAL RESULTS: Long Channel Devices • Normalized mobility variations versus applied stress: - Excellent linear dependence for both n and p MOS devices. ULIS 2003 - Udine (Italy) - C. Gallon

12. EXPERIMENTAL RESULTS: Long Channel Devices • Mobility variations and piezoresistance response: L longitudinal coefficient T transverse coefficient Majors coefficients of cubic structure for silicon ULIS 2003 - Udine (Italy) - C. Gallon

13. Bradley&al. IEEE2001 0.3µm techno. Ref. Si EXPERIMENTAL RESULTS: Long Channel Devices • Piezoresistance coefficients (.10-12Pa-1): Bulk&SOI results 0.13µm techno. ULIS 2003 - Udine (Italy) - C. Gallon

14. 8 nMOS Longitudinal Stress 6 L=10µm 4 µ/µ (%) D’ D’ 2 R R L=0.13µm D D 0 G G 0 25 50 75 100 S S R R Tensile Stress (MPa) S’ S’ EXPERIMENTAL RESULTS: Long&Short Channel Devices • Comparison between Long and Short devices: Bradley&al.: “Reduction is only due to the influence of Rsd". (IEEE 2001) ULIS 2003 - Udine (Italy) - C. Gallon

15. EXPERIMENTAL RESULTS: Short Channel Devices • Bradley approach: • Problems of this approach: - Extraction of Ron is Vg dependent - Choice in Vg extraction results in significant variation on Ron • Significant uncertainty on piezoresistive coefficients. • A novel approach is proposed. ULIS 2003 - Udine (Italy) - C. Gallon

16. EXPERIMENTAL RESULTS: Short Channel Devices • New approach proposed: 1. Correction from Rsd influence on Id0: • Calculation of equivalent Vg shift to get the same Id with and without stress: • Vg is related to Vt and mobility change by: [Roux-dit-Buisson, IEEProceedings-G, 1993] ULIS 2003 - Udine (Italy) - C. Gallon

17. 2. Normalizedmobility change versus applied uniaxial stress. 8 8 No Rsd Correction Rsd correction 6 6 4 4 Transversal 2 2 µ/µ (%) 5 0 0 100MPa - 2 Longitudinal 4 - 4 75MPa - 6 Vg=Id/Gm (10-2V) 3 - 8 50MPa 2 0 0 25 25 50 50 75 75 100 100 25MPa Tensile Stress (MPa) 1 0 3. Piezoresistive coefficients extraction. 0 0 0,1 0,1 0,2 0,2 0,3 0,3 0,4 0,4 0,5 0,5 0,6 0,6 Id/Gm (V) EXPERIMENTAL RESULTS: Short Channel Devices 1. Experimental variations after various stress levels for a 0.13µm pMOS/SOI. Note excellent linearity. ULIS 2003 - Udine (Italy) - C. Gallon

18. EXPERIMENTAL RESULTS: Short Channel Devices • Example of calculations including Rsd corrections: • Agreement between  coefficients for both short and long L. • Local or 2D stress do not affect significantly short devices, however a slight longitudinal effect may exist. ULIS 2003 - Udine (Italy) - C. Gallon

19. CONCLUSIONS & PERSPECTIVES • Study of mechanical stress effects on long and short channels. • Proposition of a simple approach to determine directly Vt and µ • Vt is independent of stress, • Mobility variations dominate the piezoresistive response, • Bulk & SOI: similar piezoresistive response both n and p MOS, slightly higher for SOI. • After Rsd corrections, comparable results on short and long devices:  2D or local effects are small for a 0.13µm technology. • A first step to provide piezoresistive data for device simulators and a better analysis of mechanical stress effects. ULIS 2003 - Udine (Italy) - C. Gallon