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2010 Electronic Materials Conference Ashish Baraskar June 23-25, 2010 – Notre Dame, IN 1 In-situ Ohmic Contacts to p-InGaAs Ashish Baraskar, Vibhor Jain,

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Presentation on theme: "2010 Electronic Materials Conference Ashish Baraskar June 23-25, 2010 – Notre Dame, IN 1 In-situ Ohmic Contacts to p-InGaAs Ashish Baraskar, Vibhor Jain,"— Presentation transcript:

1 2010 Electronic Materials Conference Ashish Baraskar June 23-25, 2010 – Notre Dame, IN 1 In-situ Ohmic Contacts to p-InGaAs Ashish Baraskar, Vibhor Jain, Evan Lobisser, Brian Thibeault, Arthur Gossard and Mark Rodwell ECE and Materials Departments, University of California, Santa Barbara, CA Mark Wistey Electrical Engineering, University of Notre Dame, IN

2 2010 Electronic Materials Conference Ashish Baraskar June 23-25, 2010 – Notre Dame, IN 2 Outline Motivation –Low resistance contacts for high speed HBTs –Approach Experimental details –Contact formation –Fabrication of Transmission Line Model structures Results –Doping characteristics –Effect of doping on contact resistivity –Effect of annealing Conclusion

3 2010 Electronic Materials Conference Ashish Baraskar June 23-25, 2010 – Notre Dame, IN 3 Outline Motivation –Low resistance contacts for high speed HBTs –Approach Experimental details –Contact formation –Fabrication of Transmission Line Model structures Results –Doping characteristics –Effect of doping on contact resistivity –Effect of annealing Conclusion

4 2010 Electronic Materials Conference Ashish Baraskar June 23-25, 2010 – Notre Dame, IN 4 Device Bandwidth Scaling Laws for HBT To double device bandwidth: Cut transit time 2x Cut RC delay 2x Scale contact resistivities by 4:1* *M.J.W. Rodwell, CSICS 2008 HBT: Heterojunction Bipolar Transistor

5 2010 Electronic Materials Conference Ashish Baraskar June 23-25, 2010 – Notre Dame, IN 5 InP Bipolar Transistor Scaling Roadmap Emitter 2561286432nm width 8421Ω·µm 2 access ρ Base 1751206030nm contact width 1052.51.25Ω·µm 2 contact ρ Collector 106755337.5nm thick 9183672mA/µm 2 current 43.32.752-2.5V breakdown fτfτ 52073010001400GHz f max 850130020002800GHz Contact resistivity serious barrier to THz technology Less than 2 Ω-µm 2 contact resistivity required for simultaneous THz f t and f max *

6 2010 Electronic Materials Conference Ashish Baraskar June 23-25, 2010 – Notre Dame, IN 6 Approach To achieve low resistance, stable ohmic contacts Higher number of active carriers - Reduced depletion width - Enhanced tunneling across metal- semiconductor interface Better surface preparation techniques - For efficient removal of oxides/impurities

7 2010 Electronic Materials Conference Ashish Baraskar June 23-25, 2010 – Notre Dame, IN 7 Scaled device thin base (For 80 nm device: t base < 25 nm) Non-refractory contacts may diffuse at higher temperatures through base and short the collector Pd/Ti/Pd/Au contacts diffuse about 15 nm in InGaAs on annealing Approach (contd.) 100 nm InGaAs grown in MBE 15 nm Pd/Ti diffusion Need a refractory metal for thermal stability

8 2010 Electronic Materials Conference Ashish Baraskar June 23-25, 2010 – Notre Dame, IN 8 Outline Motivation –Low resistance contacts for high speed HBTs and FETs –Approach Experimental details –Contact formation –Fabrication of Transmission Line Model structures Results –Doping characteristics –Effect of doping on contact resistivity –Effect of annealing Conclusion

9 2010 Electronic Materials Conference Ashish Baraskar June 23-25, 2010 – Notre Dame, IN 9 Semi-insulating InP Substrate 100 nm In 0.52 Al 0.48 As: NID buffer 100 nm In 0.53 Ga 0.47 As: C (p-type) Epilayer growth by Solid Source Molecular Beam Epitaxy (SS-MBE)– p-InGaAs/InAlAs - Semi insulating InP (100) substrate - Un-doped InAlAs buffer - CBr 4 as carbon dopant source - Hole concentration determined by Hall measurements Epilayer Growth

10 2010 Electronic Materials Conference Ashish Baraskar June 23-25, 2010 – Notre Dame, IN 10 100 nm In 0.52 Al 0.48 As: NID buffer 100 nm In 0.53 Ga 0.47 As: C (p-type) 20 nm in-situ Mo Semi-insulating InP Substrate In-situ contacts In-situ molybdenum (Mo) deposition -E-beam chamber connected to MBE chamber -No air exposure after film growth Why Mo? -Refractory metal (melting point ~ 2620 o C) -Easy to deposit by e-beam technique -Easy to process and integrate in HBT process flow

11 2010 Electronic Materials Conference Ashish Baraskar June 23-25, 2010 – Notre Dame, IN 11 TLM (Transmission Line Model) fabrication E-beam deposition of Ti, Au and Ni layers Samples processed into TLM structures by photolithography and liftoff Contact metal was dry etched in SF 6 /Ar with Ni as etch mask, isolated by wet etch 100 nm In 0.52 Al 0.48 As: NID buffer 100 nm In 0.53 Ga 0.47 As: C (p-type) 20 nm in-situ Mo 20 nm ex-situ Ti 50 nm ex-situ Ni 500 nm ex-situ Au Semi-insulating InP Substrate

12 2010 Electronic Materials Conference Ashish Baraskar June 23-25, 2010 – Notre Dame, IN 12 Resistance measured by Agilent 4155C semiconductor parameter analyzer TLM pad spacing (L gap ) varied from 0.5-26 µm; verified from scanning electron microscope (SEM) TLM Width ~ 25 µm Resistance Measurement

13 2010 Electronic Materials Conference Ashish Baraskar June 23-25, 2010 – Notre Dame, IN 13 Extrapolation errors: –4-point probe resistance measurements on Agilent 4155C –Resolution error in SEM RR dd RcRc Error Analysis Processing errors: L gap W Variable gap along width (W) 1.10 µm 1.04 µm – Variable gap spacing along width (W) Overlap Resistance – Overlap resistance

14 2010 Electronic Materials Conference Ashish Baraskar June 23-25, 2010 – Notre Dame, IN 14 Outline Motivation –Low resistance contacts for high speed HBTs and FETs –Approach Experimental details –Contact formation –Fabrication of Transmission Line Model structures Results –Doping characteristics –Effect of doping on contact resistivity –Effect of annealing Conclusion

15 2010 Electronic Materials Conference Ashish Baraskar June 23-25, 2010 – Notre Dame, IN 15 Doping Characteristics-I Hole concentration Vs CBr 4 flux – Hole concentration saturates at high CBr fluxes – Number of di-carbon defects as CBr flux T sub = 460 o C

16 2010 Electronic Materials Conference Ashish Baraskar June 23-25, 2010 – Notre Dame, IN 16 As V/III ratio hole concentration hypothesis: As-deficient surface drives C onto group-V sites Doping Characteristics-II Hole concentration Vs V/III flux CBr = 60 mtorr

17 2010 Electronic Materials Conference Ashish Baraskar June 23-25, 2010 – Notre Dame, IN 17 CBr = 60 mtorr Doping Characteristics-III Hole concentration Vs substrate temperature *Tan et. al. Phys. Rev. B 67 (2003) 035208 Tendency to form di-carbon defects as Tsub *

18 2010 Electronic Materials Conference Ashish Baraskar June 23-25, 2010 – Notre Dame, IN 18 CBr = 60 mtorr Doping Characteristics-III Hole concentration Vs substrate temperature *Tan et. al. Phys. Rev. B 67 (2003) 035208 Tendency to form di-carbon defects as Tsub *

19 2010 Electronic Materials Conference Ashish Baraskar June 23-25, 2010 – Notre Dame, IN 19 ρ c lower than the best reported contacts to pInGaAs ( ρ c = 4 Ω-µm 2 ) [1,2] 1. Griffith et al, Indium Phosphide and Related Materials, 2005. 2. Jain et al, IEEE Device Research Conference, 2010. Hole concentration, p = 1.6 x 10 20 cm -3 Mobility, µ = 36 cm 2 /Vs Sheet resistance, R sh = 105 ohm/ (100 nm thick film) Results: Contact Resistivity - I Metal Contactρ c (Ω-µm 2 )ρ h (Ω-µm) In-situ Mo2.2 ± 0.815.4 ± 2.6

20 2010 Electronic Materials Conference Ashish Baraskar June 23-25, 2010 – Notre Dame, IN 20 Tunneling  Data suggests tunneling Thermionic Emission   c ~ constant * High active carrier concentration is the key to low resistance contacts * Physics of Semiconductor Devices, S M Sze Results: Contact Resistivity - II

21 2010 Electronic Materials Conference Ashish Baraskar June 23-25, 2010 – Notre Dame, IN 21 Mo contacts annealed under N 2 flow for 60 mins. at 250 o C Thermal Stability - I ρ c increases on annealing Mo reacts with residual interfacial carbon?* *Kiniger et. al., Surf. Interface Anal. 2008, 40, 786–789 Kiniger et. al.* Molybdenum C substrate Before annealingAfter annealing ρ c (Ω-µm 2 )2.2 ± 0.82.8 ± 0.9

22 2010 Electronic Materials Conference Ashish Baraskar June 23-25, 2010 – Notre Dame, IN 22 Mo contacts annealed under N 2 flow for 60 mins. at 250 o C TEM of Mo-pInGaAs interface - Suggests sharp interface - Minimal/No intermixing 200 nm InAlAs InGaAs Mo Ti Au Thermal Stability - II

23 2010 Electronic Materials Conference Ashish Baraskar June 23-25, 2010 – Notre Dame, IN 23 Summary Maximum hole concentration obtained = 1.6 x10 20 cm -3 at a substrate temperature of 350 o C Low contact resistivity with in-situ metal contacts (lowest ρ c =2.2 ± 0.8 Ω-µm 2 ) Contacts suitable for THz transistors

24 2010 Electronic Materials Conference Ashish Baraskar June 23-25, 2010 – Notre Dame, IN 24 Thank You ! Questions? Acknowledgements ONR, DARPA-TFAST, DARPA-FLARE

25 2010 Electronic Materials Conference Ashish Baraskar June 23-25, 2010 – Notre Dame, IN 25 Extra Slides

26 2010 Electronic Materials Conference Ashish Baraskar June 23-25, 2010 – Notre Dame, IN 26 Correction for Metal Resistance in 4-Point Test Structure Error term (R metal /x) from metal resistance I I V V

27 2010 Electronic Materials Conference Ashish Baraskar June 23-25, 2010 – Notre Dame, IN 27 Random and Offset Error in 4155C Random Error in resistance measurement ~ 0.5 m  Offset Error < 5 m  * *4155C datasheet

28 2010 Electronic Materials Conference Ashish Baraskar June 23-25, 2010 – Notre Dame, IN 28 Accuracy Limits Error Calculations – dR = 50 mΩ (Safe estimate) – dW = 1 µm – dGap = 20 nm Error in ρ c ~ 40% at 1.1 Ω-µm 2

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