Straining Ge bulk and nanomembranes for optoelectronic applications: a systematic numerical analysis

Germanium is known to become a direct band gap material when subject to a biaxial tensile strain of 2% (Vogl et al 1993 Phys. Scr. T49B 476) or uniaxial tensile strain of 4% (Aldaghri et al 2012 J. Appl. Phys. 111 053106). This makes it appealing for the integration of optoelectronics into current CMOS technology. It is known that the induced strain is highly dependent on the geometry and composition of the whole system (stressors and substrate), leaving a large number of variables to the experimenters willing to realize this transition and just a trial-and-error procedure. The study in this paper aims at reducing this freedom. We adopt a finite element approach to systematically study the elastic strain induced by different configurations of lithographically-created SiGe nanostructures on a Ge substrate, by focusing on their composition and geometries. We numerically investigate the role played by the Ge substrate by comparing the strain induced on a bulk or on a suspended membrane. These results and their interpretation can provide the community starting guidelines to choose the appropriate subset of parameters to achieve the desired strain. A case of a very large optically active area of a Ge membrane is reported.

[1]  Yuji Yamamoto,et al.  Strain analysis in SiN/Ge microstructures obtained via Si-complementary metal oxide semiconductor compatible approach , 2013 .

[2]  A. J. Williamson,et al.  COMPARISON OF TWO METHODS FOR DESCRIBING THE STRAIN PROFILES IN QUANTUM DOTS , 1997, cond-mat/9711126.

[3]  Laura Polloni,et al.  Graphene audio voltage amplifier. , 2012 .

[4]  S. Timoshenko,et al.  Analysis of Bi-Metal Thermostats , 1925 .

[5]  S. Thompson,et al.  Uniaxial-process-induced strained-Si: extending the CMOS roadmap , 2006, IEEE Transactions on Electron Devices.

[6]  S. M. Hu,et al.  Stress‐related problems in silicon technology , 1991 .

[7]  S. Laux,et al.  Band structure, deformation potentials, and carrier mobility in strained Si, Ge, and SiGe alloys , 1996 .

[8]  Oliver G. Schmidt,et al.  Self-organized evolution of Ge/Si(001) into intersecting bundles of horizontal nanowires during annealing , 2013 .

[9]  James S. Harris,et al.  Strong enhancement of direct transition photoluminescence with highly tensile-strained Ge grown by molecular beam epitaxy , 2011 .

[10]  Akira Sakai,et al.  Fabrication technology of SiGe hetero-structures and their properties , 2005 .

[11]  David A. B. Miller,et al.  A micromachining-based technology for enhancing germanium light emission via tensile strain , 2012, Nature Photonics.

[12]  Lateral carrier injection to germanium for monolithic light sources , 2012, The 9th International Conference on Group IV Photonics (GFP).

[13]  B. LeRoy,et al.  Graphene on hexagonal boron nitride , 2014, Journal of physics. Condensed matter : an Institute of Physics journal.

[14]  M. Burghammer,et al.  Patterning-induced strain relief in single lithographic SiGe nanostructures studied by nanobeam x-ray diffraction , 2012, Nanotechnology.

[15]  Richard A. Soref,et al.  Advances in SiGeSn technology , 2007 .

[16]  O. Schmidt,et al.  Substrate strain manipulation by nanostructure perimeter forces , 2013 .

[17]  Y. Shiraki,et al.  Silicon–germanium (SiGe) nanostructures , 2011 .

[18]  R. Beanland Multiplication of misfit dislocations in epitaxial layers , 1992 .

[19]  O. Schmidt,et al.  Collective shape oscillations of SiGe islands on pit-patterned Si(001) substrates: a coherent-growth strategy enabled by self-regulated intermixing. , 2010, Physical Review Letters.

[20]  Jérôme Faist,et al.  Analysis of enhanced light emission from highly strained germanium microbridges , 2013, Nature Photonics.

[21]  D. Paul Si/SiGe heterostructures: from material and physics to devices and circuits , 2004 .

[22]  J. W. Matthews Defects associated with the accommodation of misfit between crystals , 1975 .

[23]  Cheng Li,et al.  A CMOS-compatible approach to fabricate an ultra-thin germanium-on-insulator with large tensile strain for Si-based light emission. , 2013, Optics express.

[24]  Peter Friedli,et al.  Direct-gap gain and optical absorption in germanium correlated to the density of photoexcited carriers, doping, and strain. , 2012, Physical review letters.

[25]  G. Strasser,et al.  Tuning the Electro-optical Properties of Germanium Nanowires by Tensile Strain , 2012, Nano letters.

[26]  P. Vogl,et al.  How to convert group-IV semiconductors into light emitters , 1993 .

[27]  Isabelle Sagnes,et al.  Control of tensile strain in germanium waveguides through silicon nitride layers , 2012 .

[28]  M. Romagnoli,et al.  An electrically pumped germanium laser. , 2012, Optics express.

[29]  J Gobrecht,et al.  Top-down fabricated silicon nanowires under tensile elastic strain up to 4.5% , 2012, Nature Communications.

[30]  J. Michel,et al.  Toward a Germanium Laser for Integrated Silicon Photonics , 2010, IEEE Journal of Selected Topics in Quantum Electronics.

[31]  M. Lagally,et al.  Tensilely strained germanium nanomembranes as infrared optical gain media. , 2013, Small.

[32]  G. Fishman,et al.  Band structure and optical gain of tensile-strained germanium based on a 30 band k⋅p formalism , 2010 .

[33]  Zoran Ikonic,et al.  Optimum strain configurations for carrier injection in near infrared Ge lasers , 2012 .

[34]  J. W. Matthews,et al.  Defects in epitaxial multilayers: I. Misfit dislocations* , 1974 .

[35]  J. W. Matthews,et al.  Defects in epitaxial multilayers , 1974 .

[36]  D. Scopece,et al.  One-dimensional Ge nanostructures on Si(001) and Si(1 1 10): Dominant role of surface energy , 2013 .

[37]  Mark Friesen,et al.  Elastically relaxed free-standing strained-silicon nanomembranes , 2006, Nature materials.

[38]  R. Bechmann,et al.  Numerical data and functional relationships in science and technology , 1969 .

[39]  Evan H. C. Parker,et al.  SiGe heterostructures for FET applications , 1998 .

[40]  G. Pizzi,et al.  Tight-binding calculation of optical gain in tensile strained [001]-Ge/SiGe quantum wells , 2010, Nanotechnology.

[41]  J. Dismukes,et al.  Lattice Parameter and Density in Germanium-Silicon Alloys1 , 1964 .

[42]  M. Lagally,et al.  Structure of elastically strain-sharing silicon(110) nanomembranes , 2007 .

[43]  Peng Huei Lim,et al.  Enhanced direct bandgap emission in germanium by micromechanical strain engineering. , 2009, Optics express.

[44]  J. Wortman,et al.  Young's Modulus, Shear Modulus, and Poisson's Ratio in Silicon and Germanium , 1965 .

[45]  R. People,et al.  Calculation of critical layer thickness versus lattice mismatch for GexSi1−x/Si strained‐layer heterostructures , 1985 .

[46]  Improvement of photoluminescence from Ge Layers with Si3N4/SiO2 Stressors , 2012, The 9th International Conference on Group IV Photonics (GFP).

[47]  R. Soref Mid-infrared photonics in silicon and germanium , 2010 .

[48]  David A. B. Miller,et al.  Device Requirements for Optical Interconnects to Silicon Chips , 2009, Proceedings of the IEEE.

[49]  A. Dimoulas,et al.  Strain-induced changes to the electronic structure of germanium , 2012, Journal of physics. Condensed matter : an Institute of Physics journal.

[50]  Jurgen Michel,et al.  Tensile-strained, n-type Ge as a gain medium for monolithic laser integration on Si. , 2007, Optics express.