Three-dimensional doping and diffusion in nano scaled devices as studied by atom probe tomography

Kambham, Ajay Kumar; Kumar, Arul; Florakis, A.; Vandervorst, Wilfried

doi:10.1088/0957-4484/24/27/275705

Cited by 35 publications

(41 citation statements)

References 31 publications

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“…In a similar fashion, N bnd /N NC can be useful for investigating dopant clustering in ULSI devices as function of Si nanovolume shape, size and interface orientation, using Atom Probe Tomography as a mass spectroscopic method with ultra-high spatial resolution. 33,34 The ratio N IF (d NC )/N NC (d NC ) presents a gauge for the impact of interface charge transfer 24,35 and interface dipoles [36][37][38] onto NCs. Both phenomena have a major influence on NC electronic and optical properties.…”

Section: Applicationsmentioning

confidence: 99%

Number series of atoms, interatomic bonds and interface bonds defining zinc-blende nanocrystals as function of size, shape and surface orientation: Analytic tools to interpret solid state spectroscopy data

König

2016

AIP Advances

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Semiconductor nanocrystals (NCs) experience stress and charge transfer by embedding materials or ligands and impurity atoms. In return, the environment of NCs experiences a NC stress response which may lead to matrix deformation and propagated strain. Up to now, there is no universal gauge to evaluate the stress impact on NCs and their response as a function of NC size dNC. I deduce geometrical number series as analytical tools to obtain the number of NC atoms NNC(dNC[i]), bonds between NC atoms N bnd (dNC[i]) and interface bonds N IF(dNC[i]) for seven high symmetry zincblende (zb) NCs with low-index faceting: {001} cubes, {111} octahedra, {110} dodecahedra, {001}-{111} pyramids, {111} tetrahedra, {111}-{001} quatrodecahedra and {001}-{111} quadrodecahedra. The fundamental insights into NC structures revealed here allow for major advancements in data interpretation and understanding of zb-and diamond-lattice based nanomaterials. The analytical number series can serve as a standard procedure for stress evaluation in solid state spectroscopy due to their deterministic nature, easy use and general applicability over a wide range of spectroscopy methods as well as NC sizes, forms and materials.

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Section: Applicationsmentioning

confidence: 99%

Number series of atoms, interatomic bonds and interface bonds defining zinc-blende nanocrystals as function of size, shape and surface orientation: Analytic tools to interpret solid state spectroscopy data

König

2016

AIP Advances

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“…Nevertheless, conformal doping is more difficult for n-type doping. This is due to the low adsorption efficiency of n-type dopants on Si surfaces that results in poor incorporation of As or P on the fin sidewalls [18,19,160,162,180]. Dopants located at the fin surface are then vulnerable to subsequent resist strip and etching processes (i.e.…”

Section: Doping Conformalitymentioning

confidence: 99%

“…dopant losses for As doped fins from 75% [180] to a recently improved value of around 25% after the strip process have been reported [162]). To avoid dopant loss after the strip process, recent studies considered the use of a rapid thermal annealing (RTA) after plasma doping in order to drive the dopants inside the fin (in-diffusion) and electrically activate them [18,19]. As an example, Fig.…”

Section: Doping Conformalitymentioning

confidence: 99%

“…affecting RSD) as well as significant gate overlap (thus degrading SCE) were observed due to the increased thermal budget [18]. More recently, Lee et al have considered the deposition of an oxide buffer layer prior to plasma doping instead of RTA, achieving about 76% of the As doped concentration retained in the Si fin after the strip process and even after ashing [162].…”

Section: Gatementioning

confidence: 99%

“…The compromise to remove damage and to control dopant activation and diffusion has driven sophisticated implantation and annealing schemes. Modern devices involve a mixture of implant species, cold and hot implants followed by processing steps at low temperatures (<650°C) combined with high temperature anneals with rapid temperature-time variations (flash and laser anneals) [18,19].…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Improved physical models for advanced silicon device processing

Pelaz

Marqués

Aboy

et al. 2017

Materials Science in Semiconductor Processing

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We review atomistic modeling approaches for issues related to ion implantation and annealing in advanced device processing. We describe how models have been upgraded to capture physical mechanisms in more detail as a response to the accuracy demanded in modern process and device modeling. Implantation and damage models based on the binary collision approximation have been improved to describe the direct formation of amorphous pockets for heavy or molecular ions. The use of amorphizing implants followed by solid phase epitaxial regrowth has motivated the development of detailed models that account for amorphization and recrystallization, considering the influence of crystal orientation and stress conditions. We apply simulations to describe the role of implant parameters to minimize residual damage, and we address doping issues that arise in non-planar structures such as FinFETs.

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Energy Offset Between Silicon Quantum Structures: Interface Impact of Embedding Dielectrics as Doping Alternative

König

Hiller

Gutsch

et al. 2014

Adv Materials Inter

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Ultrasmall silicon (Si) nanoelectronic devices require an energy shift of electronic states for n‐ and p‐conductivity. Nanocrystal self‐purification and out‐diffusion in field effect transistors cause doping to fail. Here, it is shown that silicon dioxide (SiO2) and silicon nitride (Si3N4) create energy offsets of electronic states in embedded Si quantum dots (QDs) in analogy to doping. Density functional theory (DFT), interface charge transfer (ICT), and experimental verifications arrive at the same size of QDs below which the dielectric dominates their electronic properties. Large positive energy offsets of electronic states and an energy gap increase exist for Si QDs in Si3N4 versus SiO2. Using DFT results, the SiO2/QD interface coverage is estimated with nitrogen (N) to be 0.1 to 0.5 monolayers (ML) for samples annealed in N2 versus argon (Ar). The interface impact is described as nanoscopic field effect and propose the energy offset as robust and controllable alternative to impurity doping of Si nanostructures.

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Three-dimensional doping and diffusion in nano scaled devices as studied by atom probe tomography

Cited by 35 publications

References 31 publications

Number series of atoms, interatomic bonds and interface bonds defining zinc-blende nanocrystals as function of size, shape and surface orientation: Analytic tools to interpret solid state spectroscopy data

Number series of atoms, interatomic bonds and interface bonds defining zinc-blende nanocrystals as function of size, shape and surface orientation: Analytic tools to interpret solid state spectroscopy data

Improved physical models for advanced silicon device processing

Energy Offset Between Silicon Quantum Structures: Interface Impact of Embedding Dielectrics as Doping Alternative

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