The Challenges of Ge-Condensation Technique

Terzieva, Valentina; Caymax, Matty; Souriau, Laurent; Meuris, M.; Clemente, Francesca; Benedetti, Alessandro

doi:10.1149/1.2355896

Cited by 11 publications

(8 citation statements)

References 9 publications

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“…Among the many techniques that have been proposed for production of GeOI wafers ͑layer transfer, 8 wafer bonding and grinding, 9 wafer bonding and etchback, 10 liquid phase epitaxy, 11 fully epitaxial growth using crystalline and lattice matched oxide, 12 etc.͒, the Ge condensation technique ͑also referred as thermal mixing͒ is an interesting approach ͑wafer scalability, ultrathin GeOI, etc.͒. [13][14][15] This method is based on the epitaxial growth of a Si-rich SiGe layer on a silicon-on-insulator ͑SOI͒ substrate followed by high-temperature selective oxidation of Si atoms to condense the Ge atoms in a thinner, Ge-rich SiGe layer. The peculiarity of this technique is the concomitance of two phenomena which are, namely, the selective oxidation of Si at the top SiO 2 /SiGe interface and the diffusion of Ge through the SiGe and the top Si layer of the SOI.…”

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confidence: 99%

High-Hole-Mobility Silicon Germanium on Insulator Substrates with High Crystalline Quality Obtained by the Germanium Condensation Technique

Souriau

Nguyen

Augendre

et al. 2009

J. Electrochem. Soc.

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Thin SiGe-on-insulator (SGOI) substrates with Ge content varying between 42 and 93% were produced by the Ge condensation technique and full structural characterization was carried out. In a second step, the electrical properties of these substrates were analyzed by the pseudo metal-oxide semiconductor field-effect transistor technique which allowed determination of the carrier low-field mobilities, as well as the density of fixed charges in the buried oxide (BOX) and the density of interface traps at the BOX-SiGe film interface. Optimization of intermediate anneals in argon during the condensation process made the production of high crystalline quality and high-mobility substrates possible (up to 400cm2normalV−1normals−1 for a 93% SGOI). Opposite trends were observed for holes and electrons: while the hole mobility increases with increasing Ge content, the electron mobility decreases. In addition, the density of interface traps and also the density of oxide charges were found to increase with increasing Ge content. Possible causes for this increase are discussed.

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confidence: 99%

High-Hole-Mobility Silicon Germanium on Insulator Substrates with High Crystalline Quality Obtained by the Germanium Condensation Technique

Souriau

Nguyen

Augendre

et al. 2009

J. Electrochem. Soc.

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“…A first one concerns SiO 2 /(100)Ge x Si 1-x /SiO 2 / (100)Si entities with atomic Ge fraction x in the range 0.27 ≤ x ≤ 0.93, fabricated using the condensation technique (16,17). Briefly, this essentially implies a three-step process.…”

Section: Studied Entitiesmentioning

confidence: 99%

“…In addition, monitoring of the in plane lattice constant by high-resolution x-ray diffraction measurements reveal that the SiGe film relaxes as the condensation proceeds, the data being supported by Raman observations, pointing to a remaining strain in the -0.9 to -1.2% range. More details can be found elsewhere (17,19).…”

Section: Studied Entitiesmentioning

confidence: 99%

(Invited) Identification of Intrinsic Point Defects at Ge_xSi_1-x/Oxide Interfaces by ESR Probing

et al. 2010

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We report on the obvervation by electron spin resonance (ESR) of two paramagnetic Ge dangling bond (DB)-type defects at Ge/oxide interfaces. One, detected in SiO2/(100)GexSi1-x/SiO2/Si hetero-structures grown by the condensation method, exhibits monoc-linic-I (C2v) symmetry, with principal g values g1=2.0338(3), g2=2.0386(6), g3=2.0054 and g3 axis (DB) direction 24{plus minus} 2{degree sign} off a <111> direction towards the [100] interface normal. The defect reaches maximum densities for x~0.7, to disappear for x{less than or equal to}0.45 and x{greater than or equal to}0.87. It is suggested to concern a Ge Pb1-type center, i.e., not a trigonal basic Ge Pb(0)-type center (Ge3≡Ge•), thus exposing a unique interface mismatch adaptation as function of substrate Ge fraction. The second one, observed at the interface of epitaxially grown Ge3N4/(111)Ge entities with nm-thin Ge3N4 layers, shows trigonal (C3v) symmetry characterized by g//~2.0023 and g⊥~2.0032. Based on comparision of its salient ESR features with previous theoretical results, the defect is suggested to concern the Ge K center.

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“…Several techniques have been investigated and established for preparation of GeOI substrates, the most notable amongst them being the Smart Cut TM technology, which involves transfer of Ge layers onto a Si/SiO 2 surface, from a Czochralski-grown Ge wafer [4,10,11]. Other techniques include Ge condensation [4,12] and liquid phase epitaxy (LPE) [4]. While the Smart Cut TM technology is costintensive, the two other techniques suffer from high thermal budget and limited lateral extent of GeOI (~ 20 m), respectively [4].…”

Section: Introductionmentioning

confidence: 99%

Molecular beam epitaxy and defect structure of Ge (111)/epi-Gd2O3 (111)/Si (111) heterostructures

Khiangte

Rathore

Das

et al. 2018

Journal of Applied Physics

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Molecular beam epitaxy of Ge (111) thin films on epitaxial-Gd 2 O 3 /Si(111) substrates is reported, along with a systematic investigation of the evolution of Ge growth, and structural defects in the grown epilayer. While Ge growth begins in the Volmer-Weber growth mode, the resultant islands coalesce within the first ~ 10 nm of growth, beyond which a smooth two-dimensional surface evolves.Coalescence of the initially formed islands results in formation of rotation and reflection microtwins, which constitute a volume fraction of less than 1 %. It is also observed that while the stacking sequence of the (111) planes in the Ge epilayer is similar to that of the Si substrate, the (111) planes of the Gd 2 O 3 epilayer are rotated by 180° about the [111] direction. In metal-semiconductor-metal schottky photodiodes fabricated with these all-epitaxial Ge-on-insulator (GeOI) samples, significant suppression of dark current is observed due to the presence of the Gd 2 O 3 epilayer. These results are promising for application of these GeOI structures as virtual substrates, or for realization of high-speed group-IV photonic components.

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The Challenges of Ge-Condensation Technique

Cited by 11 publications

References 9 publications

High-Hole-Mobility Silicon Germanium on Insulator Substrates with High Crystalline Quality Obtained by the Germanium Condensation Technique

High-Hole-Mobility Silicon Germanium on Insulator Substrates with High Crystalline Quality Obtained by the Germanium Condensation Technique

(Invited) Identification of Intrinsic Point Defects at Ge_xSi_1-x/Oxide Interfaces by ESR Probing

Molecular beam epitaxy and defect structure of Ge (111)/epi-Gd2O3 (111)/Si (111) heterostructures

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The Challenges of Ge-Condensation Technique

Cited by 11 publications

References 9 publications

High-Hole-Mobility Silicon Germanium on Insulator Substrates with High Crystalline Quality Obtained by the Germanium Condensation Technique

High-Hole-Mobility Silicon Germanium on Insulator Substrates with High Crystalline Quality Obtained by the Germanium Condensation Technique

(Invited) Identification of Intrinsic Point Defects at GexSi1-x/Oxide Interfaces by ESR Probing

Molecular beam epitaxy and defect structure of Ge (111)/epi-Gd2O3 (111)/Si (111) heterostructures

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Product

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(Invited) Identification of Intrinsic Point Defects at Ge_xSi_1-x/Oxide Interfaces by ESR Probing