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Low Frequency Noise in GaN-Based Advanced Electronic Devices

Low Frequency Noise in GaN-Based Advanced Electronic Devices. A Dissertation for Doctor of Philosophy By Nezih Pala Thesis Advisors: Dr. Michael Shur Dr. Remis Gaska. Talk outline. Motivation Introduction to low frequency noise Devices under study Possible noise sources in FETs

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Low Frequency Noise in GaN-Based Advanced Electronic Devices

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  1. Low Frequency Noise in GaN-Based Advanced Electronic Devices A Dissertation for Doctor of Philosophy By Nezih Pala Thesis Advisors: Dr. Michael Shur Dr. Remis Gaska

  2. Talk outline • Motivation • Introduction to low frequency noise • Devices under study • Possible noise sources in FETs • Determination of noise sources in HFETs and MESFETs • New model for 1/f noise in HFETs • Conclusions and Key Contributions

  3. Motivation • Low frequency noise is a figure of merit and limiting factor for high frequency Field Effect Transistors including HFETs and MESFETs. • Low frequency noise is upconverted to high frequencies limiting the performance of the transistors in the microwave range[1]. Especially when these devices are used as oscillators or mixers, low frequency noise limits the phase noise characteristics and degenerates the performance of the electronic system. • Low frequency noise analysis is a powerful tool for examining compound semiconductors and yielding information about crystal defects and interfaces [2]. • [1] M. N. Tutt, D. Pavlidis, A. Khatibzadeh, B. Bayraktaroglu, IEEE Trans. Microwave Theory and Tech.43, 1461-1471, (1995)[2]L. K. J. Vandamme, IEEE Trans. Elec. Devices, 41, 2176, (1994)

  4. Types of Low Frequency Noise in FETs • Thermal Noise • SV = 4kTR • SI =4kT / R • Generation- Recombination noise. • 1/f Noise Hooge Parameter

  5. Low Frequency Noise Measurement Setup • Main instrument: FFT Spectrum Analyzer SR770, Stanford Research Systems • Measurement range: 1 mHz – 100 kHz • Measurement sensitive to vibrations  air suspended table (optical table) • Measurement sensitive to electromagnetic fields and light  shielded enclosure • Use of batteries  less disturbances of power system frequencies and harmonics

  6. 7-13 nm SiO2 30 nm Si:Al0.2Ga0.8N 2x1018 50-70 nm Si:GaN (2-5)x1017 1 m i-GaN 50 nm AlN SiC/Sapphire MOS-HFET HFET 7-13 nm SiO2 50-70 nm Si:GaN (0.5-1.5) x 1018 2m GaN AlN Sapphire HD-MOSFET HD-MESFET Devices Under Study

  7. GaN Research Cycle Layout design by L-Edit RPI Epilayer growth by MOCVD USC Mask and Device Fabrication RPI,USC Characterization: DC, RF Low Frequency Noise RPI, USC 2D Simulation RPI

  8. Fabrication of GaN Based FETs I • Source/Drain ohmic metal deposition • e-beam evaporation, • Ti/Al/Ti/Au (100Å/300Å/200Å/1000Å) • Annealing at 850 oC for 60 sec. in N2 ambient • Ion implantation for isolation • He+, 40 keV, 2x1014 cm-2 • Provides planar geometry

  9. Fabrication of GaN Based FETs II • SiO2 deposition for MOS-HFET and MOSFET • type devices • Plasma Enhanced Chemical Vapor Deposition (PECVD) • SiO2 patterning and removal • BOE Etch

  10. Fabrication of GaN Based FETs III • Contact pad metal deposition • e-beam evaporation, • Ti/Au (200Å/5000Å) • Gate metal deposition • e-beam evaporation, • Ni/Au (300Å/500Å)

  11. DC Characteristics of AlGaN/GaN HFET and MOS-HFET • Several orders of of magnitude reduction in gate leakage current in MOS-HFET • Comparable Drain saturation current about 720 mA/mm. • Larger gate voltage swing for MOS-HFET. • Higher linearity in transconductance of MOS-HFET. • Decreased transconductance for MOS-HFET due to decreased gate capacitance

  12. DC Characteristics of GaN HD-MESFET HFET MESFET Lg= 1.5 m =100 cm2/Vs Ne=1.5x1018 cm-3 • High saturation current density. • RC 0.3 mm ( C ~ 1x10-6 cm2 ). • Low gate leakage current (<10 nA) indicates the quality of Schottky contacts. • Good agreement with the simulation results is encouraging for submicron devices.

  13. DC Characteristics of GaN HD-MESFET Lg= 1.5 m =100 cm2/Vs Ne=1.5x1018 cm-3 • High saturation current density. • RC 0.3 mm ( C ~ 1x10-6 cm2 ). • Low gate leakage current (<10 nA) indicates the quality of Schottky contacts.

  14. Noise spectra for HFETs and MESFETs MESFET HFET The noise spectra SId/Id2 have the form of 1/f g noise with g close to unity (g = 1.0-1.15) for both types of devices.

  15. L Lg Gate Source Drain RC RC RS1 RCh RS2 RGaN=RS1+RCh+RS2 Possible Noise Sources in FETs • 1/f noise • Contact Noise • Gate Leakage Current • Surface Noise • Channel (under the gate and source-gate, gate-drain regions) Noise • Fluctuations of the Schottky barrier space charge region (SCR) • in MESFETs • Generation-Recombination Noise

  16. L W t Contribution of Contact Noise Sources TLM Measurements (RC<<RGaN) Channel or Surface noise • SRc>>SGaN Contact noise • SRc<<SGaN Noise form the channel is dominant.

  17. V RC RS Calculation of Current Noise Density for Series Resistors

  18. Contribution of the Gate Current Fluctuations The contribution of the gate leakage current fluctuations to the output drain current noise of AlGaN/GaN HFETs was studied by three different methods: 1. The low frequency noise in the AlGaN/GaN HFETs and Metal-Oxide-Semiconductor Heterostructure Field Effect Transistors (MOS-HFETs) have been compared. 2. The gate current fluctuations were measured directly, in AlGaN/GaN HFETs. 3. The correlation between the gate and drain current fluctuations was measured and analyzed.

  19. Contribution of the Gate Current Fluctuations ■Measured ●Calculated from measured gate noise dominant contribution

  20. Correlation Between Drain and Gate Current Fluctuations Vd Drain SVg Rd Rg Vg SVd Gate Ig Source }

  21. Location of the Noise Sources in MESFETs Space charge region fluctuations noise from surface and channel out of the gate: Channel Noise a = 10-3

  22. Location of the 1/f Noise Sources in HFETs No fit indicates the concentration dependence of . channel noise noise from surface and channel out of the gate:

  23. Estimation of Electron Concentration and Mobility

  24. Hooge Parameter a as a Function of 2D Electron Concentration (Typical for tunneling[1,2]) • L. K. J. Vandamme, X. Li, and D. Rigaud, “1/f noise in MOS devices, mobility or number fluctuations?”, IEEE Transaction Electron Devices41 (1994)1936–1945 • 2. A. L. McWhorter, “1/f noise and germanium surface properties”, in Semiconductor Surface Physics, R.H. Kingston, ed., Philadelphia PA, Univ. of Pennsylvania Press (1957) 207-228

  25. C  1 D -e 2 F q x x0 AlGaN GaN New Model for 1/f Noise in Doped Channel HFETs • Tunneling into donor states in GaN • Phonon assisted tunneling • Longer jumps correspond to lower frequency noise

  26. Equations for the Tunneling Model : capture rate due to tunneling : 2D tunneling cross-section : electron momentum in 2 DEG Where :

  27. Equations for the Tunneling Model This is 1/f noise

  28. Comparison With the Experiment Theory Experiment • Very good agreement of the noise maximum amplitude and position • But the shapes of the dependencies are different • And the temperature dependence of the 1/f noise has to be checked in undoped HFETs

  29. Temperature Dependencies of Noise Density in HFETs and MOS-HFETs • Such S(T) dependencies are typical for the noise from local levels Ea= 0.8 - 1.0 eV,

  30. Al0.2Ga0.8N 3 GaN t C d F 2 Surface Channel 1 t What is the Origin of the G-R Noise? • G-R Process by a level in the channel [*] where  310-18 cm : To small to be true! Nts1026 cm-2 : To large to be true! 2) Electrons can be captured via tunneling. Might lead 1/f noise not GR noise. 3) G-R Process by a level in AlGaN barrier layer Et = 0.8 - 1.0 eV,sn » (10-12 - 10-13)cm2, Nt »5´1016 cm-3 : All reasonable values. [*] Copeland J. A., IEEE Trans. Elect. Dev. 18, 50, 1971

  31. Temperature Dependencies of Noise in HD-MESFETs and HD-MOSFETs Temperature dependence of noise in HD-MESFETs and HD-MOSFETs is weaker than the one in HFETs. Contribution of GR noise is weaker in HD-MESFETs compared to 1/f noise.

  32. Comparison of Hooge  Parameters

  33. Comparison of Hooge  Parameters References 1. R.H.,Clevers, Physica B 154, 214, (1989) 2. F.N. Hooge, M. Tacano, Physica B 190, 145, (1993) 3. M. Levinshtein, S. Rumyantsev, J. Plamour, D. Slater, J. Appl. Phys. 81, 1758, (1997) 4. M. Tacano and Y. Sugiyama, Solid State Elect., Vol. 34. No 10, pp.1049-53, 1991. 5.D. Fleetwood, T.L. Meisenheimer, J. Scofield, IEEE Trans. Elct. Dev. Vol. 41, No 11, p. 1936 6. L.K. J Vandamme, X. Li, D. Rigaud, IEEE Trans. Elct. Dev. Vol. 41, No:11, p. 1936, Nov. 1994 7. Present Work 8. A. Balandin, S. Morozov, G. Wijeratne, C. Cai, L. Wang, C. Viswanathan, Appl. Phys. Lett., 75, No. 14, p.2064, (1999) 9.S. Rumyantsev, M.E.Levinshtein, R. Gaska, M. S. Shur, J. W. Jang, and M. A. Khan, J. Appl. Phys. 87, N4 pp.1849-1854, (2000) 10. N. Pala, R. Gaska, S. Rumyantsev, M. S. Shur M. Asif Khan, X. Hu, G. Simin, and J. Yang, Electronics Letters, vol. 36, No. 3, p. 268, Feb. 2000. 11.S. L. Rumyantsev, N. Pala, M. S. Shur, R. Gaska, M. E. Levinshtein, M. Asif Khan, G. Simin, X. Hu, and J. Yang, Electronics Letters, Submitted 12. M. E. Levinshtein and S. L. Rumyantsev, Techn. Phys. Lett. vol. 19, no. 7-8, pp. 55-59, 1993 13.N.V. Dyakonova, M.E. Levinshtein, S. Contreras, W. Knap, B. Beaumont, P. Gibart.,"Low-frequency noise in GaN" Semiconductors. v.32, N 3, pp.257-260,(1998), March

  34. Conclusions (HFETs) • Hooge parameter a = 10-3 - 10-5 for both HFETs and MOS-HFETs. SiO2 deposited on AlGaN in MOS-HFETs does not contribute much to noise. • In the devices with low gate leakage current the contribution of the gate leakage current to the low frequency noise of drain current is fully masked by other noise mechanisms. • In the transistors with no contribution of the gate leakage current to the output noise the noise sources are located in the channel. • Hooge parameter a is inversely proportional to the channel concentration in GaN/AlGaN HFETs – typical for tunneling mechanism. The model based on this mechanism is in qualitative agreement with our experimental data but the agreement must be checked further for undoped HFETs. • Generation-recombination noise with activation energy of Ea ~ 0.8 - 1.0 eV has been found in both HFETs and MOS-HFETs. The analysis shows that the trap responsible for the observed generation-recombination noise can be located in the AlGaN barrier layer.

  35. Conclusions (MESFETs) • The noise properties of MESFETs and MOSFETs are similar. Hooge parameter a = (2-3)10-3 for both devices. • This value is about one order of magnitude smaller than the value of a reported for bulk n-type GaN. • Drain and source contacts do not contribute much to the low frequency noise. • The noise originates from the bulk of GaN in the channel and in the source to gate and drain to gate regions. • The temperature dependence of noise shows a weak contribution of • generation-recombination noise at elevated temperatures.

  36. Key Contributions • Design and fabrication of MOS-HFET with SiO2 as gate dielectric: • Reduction in gate leakage current six orders of magnitude, • Design and fabrication of HD-MESFET : • Comparable output characteristics with HFETs with the advantages of simpler epilayer structure. • Systematic measurement and analysis of low frequency noise to determine: • Effect of gate leakage current , • Location of trap level causing GR noise, • Origin of 1/f noise, • Concentration dependence of 1/f noise. • Development of a new model to explain 1/f noise in doped channel HFETs.

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