PECVD low stress silicon nitride analysis and optimization for the fabrication of CMUT devices

Two technological options to achieve a high deposition rate, low stress plasma-enhanced chemical vapor deposition (PECVD) silicon nitride to be used in capacitive micromachined ultrasonic transducers (CMUT) fabrication are investigated and presented. Both options are developed and implemented on standard production line PECVD equipment in the framework of a CMUT technology transfer from R & D to production. A tradeoff between deposition rate, residual stress and electrical properties is showed.The first option consists in a double layer of silicon nitride with a relatively high deposition rate of ~100 nm min−1 and low compressive residual stress, which is suitable for the fabrication of the thick nitride layer used as a mechanical support of the CMUTs. The second option involves the use of a mixed frequency low-stress silicon nitride with outstanding electrical insulation capability, providing improved mechanical and electrical integrity of the CMUT active layers. The behavior of the nitride is analyzed as a function of deposition parameters and subsequent annealing. The nitride layer characterization is reported in terms of interfaces density influence on residual stress, refractive index, deposition rate, and thickness variation both as deposited and after thermal treatment. A sweet spot for stress stability is identified at an interfaces density of 0.1 nm−1, yielding 87 MPa residual stress after annealing. A complete CMUT device fabrication is reported using the optimized nitrides. The CMUT performance is tested, demonstrating full functionality in ultrasound imaging applications and an overall performance improvement with respect to previous devices fabricated with non-optimized silicon nitride.

[1]  M. Pappalardo,et al.  Building CMUTs for imaging applications from top to bottom , 2007 .

[2]  Edward Hæggström,et al.  Fabricating capacitive micromachined ultrasonic transducers with wafer-bonding technology , 2003 .

[3]  E.P. van de Ven,et al.  Advantages of dual frequency PECVD for deposition of ILD and passivation films , 1990, Seventh International IEEE Conference on VLSI Multilevel Interconnection.

[4]  H. Ezzaouia,et al.  The effect of thermal annealing on the properties of PECVD hydrogenated silicon nitride , 2012 .

[5]  C. Chao,et al.  Novel multilayered Ti/TiN diffusion barrier for Al metallization , 2005 .

[6]  A. Bagolini,et al.  Influence of interfaces density and thermal processes on mechanical stress of PECVD silicon nitride , 2009 .

[7]  J. McLean,et al.  Low temperature fabrication of immersion capacitive micromachined ultrasonic transducers on silicon and dielectric substrates , 2004, IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control.

[8]  M. Pappalardo,et al.  Curvilinear capacitive micromachined ultrasonic transducer (CMUT) array fabricated using a reverse process , 2008, 2008 IEEE Ultrasonics Symposium.

[9]  Chao Wang,et al.  Analytical characterization using surface-enhanced Raman scattering (SERS) and microfluidic sampling , 2015, Nanotechnology.

[10]  D. Giubertoni,et al.  Correlation between silicon‐nitride film stress and composition: XPS and SIMS analyses , 2006 .

[11]  C. W. Pearce,et al.  Characteristics of silicon nitride deposited by plasma‐enhanced chemical vapor deposition using a dual frequency radio‐frequency source , 1992 .

[12]  S. P. Murarka,et al.  Metallization: Theory and practice for VLSI and ULSI , 1992 .

[13]  A. S. Savoia,et al.  A CMUT probe for medical ultrasonography: from microfabrication to system integration , 2012, IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control.

[14]  Bustarret,et al.  Configurational statistics in a-SixNyHz alloys: A quantitative bonding analysis. , 1988, Physical review. B, Condensed matter.

[15]  Alessandro Stuart Savoia,et al.  Enhanced echographic images obtained improving the membrane structural layer of the cMUT probe , 2005, IEEE Ultrasonics Symposium, 2005..

[16]  Bhushan Sopori,et al.  Silicon nitride processing for control of optical and electronic properties of silicon solar cells , 2003 .

[17]  Vittorio Foglietti,et al.  Improvements towards a reliable fabrication process for cMUT , 2003 .

[18]  A. Savoia,et al.  Performance optimization of a high frequency CMUT probe for medical imaging , 2011, 2011 IEEE International Ultrasonics Symposium.

[19]  G. Stoney The Tension of Metallic Films Deposited by Electrolysis , 1909 .

[20]  A. Iula,et al.  Design and fabrication of a cMUT probe for ultrasound imaging of fingerprints , 2010, 2010 IEEE International Ultrasonics Symposium.

[21]  Abdullah Atalar,et al.  Silicon micromachined ultrasonic immersion transducers , 1996 .

[22]  Alessandro Stuart Savoia,et al.  Capacitive micromachined ultrasonic transducer (cMUT) made by a novel "reverse fabrication process" , 2005, IEEE Ultrasonics Symposium, 2005..

[23]  Vittorio Foglietti,et al.  Fabrication of capacitive micromechanical ultrasonic transducers by low-temperature process , 2002 .

[24]  O. Oralkan,et al.  Capacitive micromachined ultrasonic transducers: fabrication technology , 2005, IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control.

[25]  W. Claassen,et al.  Influence of Deposition Temperature, Gas Pressure, Gas Phase Composition, and RF Frequency on Composition and Mechanical Stress of Plasma Silicon Nitride Layers , 1985 .

[26]  Vittorio Foglietti,et al.  Dual frequency PECVD silicon nitride for fabrication of CMUTs' membranes , 2006 .

[27]  Alessandro Stuart Savoia,et al.  A high frequency cMUT probe for ultrasound imaging of fingerprints , 2011 .

[28]  Optical characterization of hydrogenated amorphous silicon thin films deposited at high rate , 1999 .