Abnormal hole mobility of biaxial strained Si

Liao, Ming-Han; Chang, Shu−Tong; Lee, M. H.; Maikap, S.; C, Liu

doi:10.1063/1.2041839

Cited by 18 publications

(4 citation statements)

References 13 publications

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“…The simulation results about hole mobility at room temperature are consistent with the results of refs. [16,17] about inversion layer in stained silicon, all of which change non-monotonically with germanium content. At room temperature, the hole mobility is still lower than that of electron under the same strain conditions and impurity concentration [18], because ionized impurity scattering of hole varies with germanium content evidently due to the effect of both top band occupancy and density-of-state effective mass as Figures 1 and 2 show.…”

Section: Simulation Resultsmentioning

confidence: 96%

Hole mobility of strained Si/(001)Si1−x Ge x

Wang

Zhang

et al. 2011

Sci. China Phys. Mech. Astron.

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The hole mobility of strained silicon along the <110> orientation on (001) Si 1x Ge x is obtained by solving collision term in the Boltzmann transport equation. The analytical model is proposed that considers the effect of strain-induced splitting at valence band valleys in silicon, doping dependence and three scattering mechanisms, i.e., ionized impurity scattering, acoustic phonon scattering and non-polar optical phonon scattering. The hole occupancy at top band indicates a non-monotonic variation under biaxial tensile strain at low temperature (77 K). What's more, a non-monotonic variation of hole mobility at room temperature (300 K) is presented. Compared with the room temperature hole mobility, the low temperature hole mobility is affected greatly by ionized impurity scattering at lower impurity concentration. At the same time, the room temperature hole mobility is lower than that of electron with the same germanium content and doping concentration. If the parameters are correctly chosen, the model can also be used to calculate the hole mobility of other crystal faces with arbitrary orientation. So, it lays a useful foundation for strained silicon devices and circuits. subband hole occupancy, scattering model, germanium content, hole mobility PACS number(s): 71.70.Fk, 71.23.An, 73.75.Dn Citation: Wang X Y, Zhang H M, Ma J L, et al. Hole mobility of strained Si/(001)Si 1x Ge x .

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Section: Simulation Resultsmentioning

confidence: 96%

Hole mobility of strained Si/(001)Si1−x Ge x

Wang

Zhang

et al. 2011

Sci. China Phys. Mech. Astron.

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“…Consequently much higher levels of strain are required to enhance the hole mobility. This effect is shown in figure 4(d) [7]; however, some reports indicate both a less dramatic degradation of hole mobility at low strain and an enhancement that begins at strains as low as 0.3% [40].…”

Section: Band Structure Modificationmentioning

confidence: 98%

“…Unlike the electron mobility, the hole mobility is complicated by a warping of the valence band with strain. The effective mass initially increases with small amounts of strain, degrading the mobility [40]. With increasing tensile strain, the energy of the light-hole band is raised relative to that of the heavy-hole band and the mobility begins to demonstrate an enhancement as more holes are occupied in the light-hole band.…”

Section: Band Structure Modificationmentioning

confidence: 99%

Elastically strain-sharing nanomembranes: flexible and transferable strained silicon and silicon–germanium alloys

Scott¹,

Lagally²

2007

J. Phys. D: Appl. Phys.

118

103

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The emerging field of strained-Si based nanomembranes is reviewed, including fabrication techniques, strain-induced band structure engineering, electronic applications and three-dimensional membrane architectures. Elastic strain sharing between thin heteroepitaxial Si and SiGe films, enabled by techniques that allow release of these films from a handling substrate, creates a new material: freestanding, single-crystal, strained nanomembranes. These flexible nanomembranes are virtually dislocation-free and have many potential new applications. Strain engineering also provides opportunities for massively parallel self-assembly of a wide variety of three-dimensional nanostructures.

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“…Strain is extensively used in the current semiconductor industry [1][2][3] including solar cell devices [4] and light-emitting diodes (LEDs) [5] because it can change material properties such as energy band structure [6], carrier effective mass [6], and radiative recombination rates [5]. One of the key stressors in the current industry is called an Epi-layer stressor [7].…”

Section: Introductionmentioning

confidence: 99%

Residual Stress of Curvature Sapphire Substrate with GaN Film Released by the Application of Trench Structures

Liao

Lee

Chen

et al. 2013

AUSMT

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Serious wafer curvature and residual stress are formed during the growth of an epi-GaN layer on Sapphire substrates due to the different thermal expansion coefficients in these two materials. By using theoretical analysis and a simulation model using the finite element method to describe the realistic shape of wafer curvature on epi-GaN wafers, we examine the influence which different thickness and thermal expansion coefficients in the top epi-GaN layer have on wafer curvature reduction. In addition a new process to reduce wafer curvature and to relax residual stress is proposed. With an additional laser treatment on a sample surface after the growth of the top epi-GaN layer on a Sapphire substrate has taken place, the wafer curvature can be reduced to ~ 37 m from the original ~ 45 m in 2 inch wafers with an optimized surface structure design.

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Abnormal hole mobility of biaxial strained Si

Cited by 18 publications

References 13 publications

Hole mobility of strained Si/(001)Si1−x Ge x

Hole mobility of strained Si/(001)Si1−x Ge x

Elastically strain-sharing nanomembranes: flexible and transferable strained silicon and silicon–germanium alloys

Residual Stress of Curvature Sapphire Substrate with GaN Film Released by the Application of Trench Structures

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