T. Hackbarth scite author profile

We report on the fabrication of modulation-doped compressively strained Ge quantum wells by low-energy plasma enhanced chemical vapor deposition. A virtual substrate consisting of a thick linearly graded SiGe buffer layer and a cap layer of constant composition is first grown at a high rate (>5 nm/s). The active layer stack, grown at a reduced rate, contains strain compensating cladding layers with modulation doping above the channel. Mobilities of up to 3000 cm2/V s and 87 000 cm2/V s have been achieved at room temperature and liquid He temperature, respectively.

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Strain relaxation mechanism for hydrogen-implanted Si1−xGex/Si(100) heterostructures

Trinkaus

Holländer

Rongen

et al. 2000

120

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A mechanism of strain relief of H+ ion implanted and annealed pseudomorphic Si1−xGex/Si(100) heterostructures grown by molecular beam epitaxy is proposed and analyzed. Complete strain relaxation was obtained at temperatures as low as 800 °C and the samples appeared free of threading dislocations within the SiGe layer to the limit of transmission electron microscopy analysis. In our model, H filled nanocracks are assumed to generate dislocation loops, which glide to the interface where they form strain relieving misfit segments. On the basis of this assumption, the conditions for efficient strain relaxation are discussed.

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Low-energy plasma-enhanced chemical vapor deposition for strained Si and Ge heterostructures and devices

Isella

Chrastina

Rössner

et al. 2004

Solid-State Electronics

143

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Effect of helium ion implantation and annealing on the relaxation behavior of pseudomorphic Si1−xGex buffer layers on Si (100) substrates

Luysberg

Kirch

Trinkaus

et al. 2002

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The influence of He implantation and annealing on the relaxation of Si 0.7 Ge 0.3 layers on Si ͑100͒ substrates is investigated. Proper choice of the implantation energy results in a narrow defect band Ϸ100 nm underneath the substrate/epilayer interface. During annealing at 700-1000°C, He-filled bubbles are created, which act as sources for misfit dislocations. Efficient annihilation of the threading dislocations is theoretically predicted, if a certain He bubble density with respect to the buffer layer thickness is maintained. The variation of the implantation dose and the annealing conditions changes density and size of spherical He bubbles, resulting in characteristic differences of the dislocation structure. Si 1Ϫx Ge x layers with Ge fractions up to 30 at. % relax the initial strain by 70% at an implantation dose of 2ϫ10 16 cm Ϫ2 and an annealing temperature as low as 850°C. Simultaneously, a low threading dislocation density of 10 7 cm Ϫ2 is achieved. The strain relaxation mechanism in the presence of He filled bubbles is discussed.

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Strain relaxation of epitaxial SiGe layers on Si(100) improved by hydrogen implantation

Mantl¹,

Holländer²,

Liedtke³

et al. 1999

Nuclear Instruments and Methods in Physics Research Section B:

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T. Hackbarth

Very high hole mobilities in modulation-doped Ge quantum wells grown by low-energy plasma enhanced chemical vapor deposition

Strain relaxation mechanism for hydrogen-implanted Si1−xGex/Si(100) heterostructures

Low-energy plasma-enhanced chemical vapor deposition for strained Si and Ge heterostructures and devices

Effect of helium ion implantation and annealing on the relaxation behavior of pseudomorphic Si1−xGex buffer layers on Si (100) substrates

Strain relaxation of epitaxial SiGe layers on Si(100) improved by hydrogen implantation

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