Fabrication, structural and electrical properties of (1 1 0) localized silicon-on-insulator devices

Destefanis, V.; Hartmann, Jean‐Michel; Huguenin, J.-L.; Delaye, V.; Samson, M.-P.; Boulitreau, P.; Morand, Y.; Brianceau, P.; Arvet, C.; Gautier, P.; Monfray, S.; Skotnicki, T.

doi:10.1088/0268-1242/25/4/045014

Cited by 10 publications

(15 citation statements)

References 22 publications

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“…6). Such a (1 1 0) surface roughening by HCl has also been noticed at 675 1C for a 210 nm deep recess of Si windows [26]. We have plotted the rms roughness and Z range values corresponding to the different Si areas recessed at 750 1C in Fig.…”

Section: Deep Hcl Recesssupporting

confidence: 65%

“…Such a (1 1 0) surface roughening by HCl can be deleterious to the planarity of thin, pseudomorphic layers selectively grown in recessed areas, as shown in Ref. [26]. Here, given that we have investigated the growth of rather thick, relaxed Ge(1 1 0) layers with heavily defective Si substrate/Ge epilayer interfaces (due to the large lattice mismatch), this surface roughening is not so critical.…”

Section: Deep Hcl Recessmentioning

confidence: 90%

“…750 1C) than the one used in Ref. [26] to etch several tens of nm of Si in the windows of Si(1 1 0) patterned areas (i.e. 675 1C), in order to obtain several hundreds of nm deep Si(1 1 0) recesses.…”

Section: Deep Hcl Recessmentioning

confidence: 99%

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Selective epitaxial growth of Ge(110) in trenches using the aspect ratio trapping technique

Destefanis

Hartmann

Baud

et al. 2010

Journal of Crystal Growth

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Section: Deep Hcl Recesssupporting

confidence: 65%

Section: Deep Hcl Recessmentioning

confidence: 90%

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Selective epitaxial growth of Ge(110) in trenches using the aspect ratio trapping technique

Destefanis

Hartmann

Baud

et al. 2010

Journal of Crystal Growth

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“…Thermal budget minimization is indeed a must, as (110) SiGe / Si heterostructures are more prone to plastic relaxation than (100) stacks (see Ref. (13) and references therein).…”

Section: Blanket Si(110) and (100) Vertical Etch Ratesmentioning

confidence: 99%

“…We have recently highlighted the promises of (110) L-SOI p-type MOSFETs (13). Such device architectures call upon several rather specific epitaxy and etch steps (14), which are surface orientation dependant (13), (15): (i) the gaseous HCl etch of Si in the active area (in order to avoid subsequent faceting), (ii) the Selective Epitaxial Growth (SEG) of {SiGe / Si} stacks with individual layer thickness in the 10 to 20 nm range and (iii) the SEG of Si Raised Sources and Drains (after the HfO 2 / TiN / poly-Si gate stack deposition and patterning). The Ge concentration of the SiGe sacrificial layer under the Si layer (which is the conduction layer of charge carriers) should be superior or equal to 20% in order to obtain a good lateral SiGe versus Si selective etch.…”

Section: Introductionmentioning

confidence: 99%

HCl Selective Etching of SiGe versus Si in Stacks Grown on (110)

Hartmann¹,

Destefanis²,

Rabille³

et al. 2010

ECS Trans.

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We have investigated the lateral HCl selective etching of SiGe versus Si in various patterned (110) SiGe/Si stacks. Given that Si(110) vertical etch rates are roughly 4 times higher than Si(100) ones for T < 850°C, a moderate HCl partial pressure (0.4 Torr) was adopted for this study, which was conducted in the 600-700°C temperature range. A definite SiGe versus Si etch selectivity has conclusively been demonstrated on (110) for 30-40% of Ge. SiGe could however not be selectively removed in stacks with 20% of Ge. SiGe lateral etch rates 1.5 to 4 times higher in the [1-10] than in the [001] direction have also been evidenced. A definite increase of both [1-10] and [001] lateral etch rates occurred when increasing the Ge content (up to x90 along [1-10] for 15 nm thick Si 0.6 Ge 0.4 layers compared to Si (110)). Increasing the etch temperature also led to a dramatic increase of those etch rates (with roughly 40 and 50 kcal. mol. -1 activation energies along [001] and [1-10], respectively). Given that etch rate activation energies were lower for SiGe than for Si (75 kcal. mol. -1 ), selectivity increased as temperature decreased. Mean selectivities for 15 nm thick layers were however not that high, 20 for Si 0.7 Ge 0.3 and 60 for Si 0.6 Ge 0.4 . Thicker SiGe layers were otherwise etched faster than thinner ones. The etch rate increase with thickness was however more important in the [001] than in the [1-10] direction (x 5 and x 3 when switching from 10 to 20 nm thick Si 0.6 Ge 0.4 layers, respectively), partially compensating the etch anisotropy.

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Epitaxy of Strained Si/Si_1‐xGe_xHeterostructures

Hartmann

2013

Silicon Technologies

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Fabrication, structural and electrical properties of (1 1 0) localized silicon-on-insulator devices

Cited by 10 publications

References 22 publications

Selective epitaxial growth of Ge(110) in trenches using the aspect ratio trapping technique

Selective epitaxial growth of Ge(110) in trenches using the aspect ratio trapping technique

HCl Selective Etching of SiGe versus Si in Stacks Grown on (110)

Epitaxy of Strained Si/Si_1‐xGe_xHeterostructures

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Fabrication, structural and electrical properties of (1 1 0) localized silicon-on-insulator devices

Cited by 10 publications

References 22 publications

Selective epitaxial growth of Ge(110) in trenches using the aspect ratio trapping technique

Selective epitaxial growth of Ge(110) in trenches using the aspect ratio trapping technique

HCl Selective Etching of SiGe versus Si in Stacks Grown on (110)

Epitaxy of Strained Si/Si1‐xGexHeterostructures

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Product

Resources

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Epitaxy of Strained Si/Si_1‐xGe_xHeterostructures