The High-Mobility Bended n-Channel Silicon Nanowire Transistor

Moselund, Kirsten E.; Najmzadeh, Mohammad; Dobrosz, P.; Olsen, SH; Bouvet, D.; Michielis, L. De; Pott, V.; Ionescu, Adrian M.

doi:10.1109/ted.2010.2040939

Cited by 42 publications

(33 citation statements)

References 40 publications

(52 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…From a materials point of view our results are also unique as they demonstrate extremely high uniform strain along x, y and z orthogonal directions (see Fig. 2b) in contrast to those found in a NW bending geometry 21 . The strain levels are still lower than the theoretical tensile strength of a brittle material, which is expected to be ~E/10, where E is the Young`s modulus.…”

Section: Discussionmentioning

confidence: 63%

“…A feasible approach would be, for example, to employ the well-established gate-all-around architeture 10,21 . In order to realize this design, we propose employing a gate last process in order to avoid strain relaxation, where activation of source and drain is performed before patterning, and where low temperature conformal deposition of high-κ gate oxide and metal gate is achieved using atomic layer deposition 22 .…”

Section: Discussionmentioning

confidence: 99%

See 1 more Smart Citation

Top-down fabricated silicon nanowires under tensile elastic strain up to 4.5%

et al. 2012

View full text Add to dashboard Cite

strained si nanowires are among the most promising transistor structures for implementation in very large-scale integration due to of their superior electrostatic control and enhanced transport properties. Realizing even higher strain levels within such nanowires are thus one of the current challenges in microelectronics. Here we achieve 4.5% of elastic strain (7.6 GPa uniaxial tensile stress) in 30 nm wide si nanowires, which considerably exceeds the limit that can be obtained using siGe-based virtual substrates. our approach is based on strain accumulation mechanisms in suspended dumbbell-shaped bridges patterned on strained si-on-insulator, and is compatible with complementary metal oxide semiconductor fabrication. Potentially, this method can be applied to any tensile prestrained layer, provided the layer can be released from the substrate, enabling the fabrication of a variety of strained semiconductors with unique properties for applications in nanoelectronics, photonics and photovoltaics. This method also opens up opportunities for research on strained materials.

show abstract

Section: Discussionmentioning

confidence: 63%

Section: Discussionmentioning

confidence: 99%

Top-down fabricated silicon nanowires under tensile elastic strain up to 4.5%

et al. 2012

View full text Add to dashboard Cite

show abstract

“…The suspended ribbons are anchored on both edges, and hence the biaxial tensile stress in the ribbons generally generates a boat shape because of (Figure 1b). 27,28 The extent and distribution of strain can be evaluated by analyzing the degree of buckling and the deformed shape. 29 Figure 1c presents the result of a three-dimensional height profile of the suspended Si/SiO 2 ribbon measured by white light interferometry.…”

Section: Roll-based Transfer Processesmentioning

confidence: 99%

Mobility enhancement of strained Si transistors by transfer printing on plastic substrates

et al. 2016

View full text Add to dashboard Cite

Strain engineering has been utilized to overcome the limitation of geometric scaling in Si-based thin-film transistor (TFT) technology by significantly improving carrier mobility. However, current strain engineering methods have several drawbacks: they generate atomic defects in the interface between Si and strain inducers, they involve high-cost epitaxial depositions and they are difficult to apply to flexible electronics with plastic substrates. Here, we report the formation of a strained Si membrane with oxidation-induced residual strain by releasing a host Si substrate of a silicon-on-insulator (SOI) wafer. The construction of the suspended Si/SiO 2 structures induces 40.5% tensile strain on the top Si membrane. The fabricated TFTs with strained Si channels are transferred onto plastics using a roll-based transfer technique, and they exhibit a mobility enhancement factor of 1.2-1.4 compared with an unstrained Si TFT.

show abstract

“…To extract the low-field electron mobility, a cylindrical model, similar to [16], was used to expect the C ox value for the GAA deeply scaled nanowires. In this work, the extracted low-field electron mobility at V DS = 100 mV is 332 cm 2 /V s, 32% higher than bulk Si electron mobility at the same level of doping (1 Â 10 18 cm À3 ) [17], which is an evidence of including uniaxial tensile stress in the channel, and possibly a higher level can be achieved in this level of stress [7] in the case of an optimum dielectric-channel interface quality especially for the deeply scaled channels [18].…”

Section: Low-field Electron Mobility Extraction In Accumulation Regimementioning

confidence: 99%

Accumulation-mode gate-all-around si nanowire nMOSFETs with sub-5nm cross-section and high uniaxial tensile strain

Najmzadeh¹,

Bouvet²,

Grabinski³

et al. 2012

Solid-State Electronics

View full text Add to dashboard Cite

a b s t r a c tIn this work we report dense arrays of accumulation-mode gate-all-around Si nanowire nMOSFETs with sub-5 nm cross-sections in a highly doped regime. The integration of local stressor technologies (both local oxidation and metal-gate strain) to achieve P2.5 GPa uniaxial tensile stress in the Si nanowire is reported. The deeply scaled Si nanowire including such uniaxial tensile stress shows a low-field electron mobility of 332 cm 2 /V s at room temperature, 32% higher than bulk mobility at the equivalent high channel doping. The conduction mechanism as well as high temperature performance was studied based on the electrical characteristics from room temperature up to %400 K and a V TH drift of À1.72 mV/K and an ionized impurity scattering-based mobility reduction were observed.

show abstract

The High-Mobility Bended n-Channel Silicon Nanowire Transistor

Cited by 42 publications

References 40 publications

Top-down fabricated silicon nanowires under tensile elastic strain up to 4.5%

Top-down fabricated silicon nanowires under tensile elastic strain up to 4.5%

Mobility enhancement of strained Si transistors by transfer printing on plastic substrates

Accumulation-mode gate-all-around si nanowire nMOSFETs with sub-5nm cross-section and high uniaxial tensile strain

Contact Info

Product

Resources

About