Electron Microscopy of As Supersaturated Silicon

Armigliato, A.; Nobili, D.; Solmi, S.; Bourret, A.; Werner, P.

doi:10.1149/1.2108471

Cited by 39 publications

(13 citation statements)

References 14 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Two more pieces of experimental data have recently been reported which have attempted to reveal the atomistic identity of electrically inactive As. One is the detection by transmission electron microscopy of very small (15 -30 A) As precipitates (Armigliato, Nobili, Solmi, Bourret, and Werner, 1986), although in concentrations too low to account for all of the electrically inactive As. The other is the use of extended x-ray-absorption finestructure spectroscopy (EXAFS) of heavily As-doped silicon (Erbil, Cargill, and Boehme, 1985;Erbil, Weber, Cargill, and Boehme, 1986), indicating localized regions of Si and As on alternating lattice sites, similar to the arrangement of Ga and As atoms in GaAs.…”

Section: Precipitation and Clusteringmentioning

confidence: 99%

Point defects and dopant diffusion in silicon

1989

View full text Add to dashboard Cite

Diffusion in silicon of elements from columns III and V of the Periodic Table is reviewed in theory and experiment. The emphasis is on the interactions of these substitutional dopants with point defects {vacancies and interstitials) as part of their diffusion mechanisms. The goal of this paper is to unify available experimental observations within the framework of a set of physical models that can be utilized in computer simulations to predict diffusion processes in silicon. The authors assess the present state of experimental data for basic parameters such as point-defect diffusivities and equilibrium concentrations and address a number of questions regarding the mechanisms of dopant diffusion. They offer illustrative examples of ways that diffusion may be modeled in one and two dimensions by solving continuity equations for point defects and dopants. Outstanding questions and inadequacies in existing formulations are identified by comparing computer simulations with experimental results. A summary of the progress made in this field in recent years and of directions future research may take is presented.

show abstract

Section: Precipitation and Clusteringmentioning

confidence: 99%

Point defects and dopant diffusion in silicon

1989

View full text Add to dashboard Cite

show abstract

“…The formation of a second phase upon heating an S i p or SiAs supersaturated solid solution has been demonstrated [1 to 31. I n case of arsenic implanted silicon, we have recently observed by weak-beam E M and HREM the presence of precipitates having a diameter ranging from 1.5 u p t o 3 nm, but their density was not sufficiently large to account for the amount of inactive As, as deduced from electrical me asurements [4]. To solve this discrepancy, we have determined a visibility criterion for small SiAs particles, according t o which in areas thicker than 10 nm these precipitates are invisible [5].…”

Section: Introductionmentioning

confidence: 98%

Contrast of small SiX particles in silicon by computed HREM images

Armigliato

Bourret

Frabboni

et al. 1988

Phys. Stat. Sol. (a)

Self Cite

View full text Add to dashboard Cite

The contrast in HREM images of small spherical coherent precipitates in silicon, having a hypothetical sphalerite structure and an S i x composition, is computed by the multislice method; X represents a dopant (or impurity) atom, ranging from boron u p t o platinum. The particles are assumed to have a diameter of 2 nm and t o exert different amounts of in situ strain E on the silicon matrix. The ideal case of no misfit ( E = 0) is also considered. For in situ strains 0 < 6 < 2y0, the maximum contrast, corresponding to the optimum defocus, depends mainly on the atomic number of the element X. For larger strains, which can occur in some cases if the Si-X bond length in the Six particle is determined by the covalent radius of the impurity atom X, the strain contrast dominates over the structure factor contrast.Der Kontrast in hochauflosenden, elektronenmikroskopischen Abbildungen kleiner, kugelformiger, koharenter Ausscheidungen in Silizium, die eine hypothetische Sphaleritstruktur und die Zusammensetzung S i x haben, wird mittels der Vielschichtmethode berechnet; X stellt hier ein Dotierungs-bzw. Verunreinigungsatom von Bor bis Platin dar. Es wird angenommen, daS die Ausscheidungen einen Durchmesser von 2 nm haben und verschiedene in-situ-Dehnunsen E auf die Siliziummatrix ausiiben. Der Idealfall, wo keine Fehlanpassung ( E = 0) vorhanden ist, wird auch betrachtet. Fur 0 < E < 2y0 ist der maximale Kontrast, der der optimalen Defokussierung entspricht, hauptsiichlich yon der Atomzahl des X-Elementes abhangig. F u r groCere Dehnungen, die in einigen Fallen vorkommen konnen, wenn die Si-X-Bindungslange im Six-Teilchen vom kovalenten Radius des X-Verunreinigungsatoms bestimmt wird, iiberwiegt der Dehnungekontrast den Strukturfaktorkontrast.

show abstract

“…In the literature, the formation of arsenic clusters/precipitates has been studied mainly in silicon wafers implanted with arsenic at levels higher than the solubility limit, up to 4 × 10 21 cm −3 , where they are considered responsible for a fraction of electrically inactive arsenic. [19][20][21][22] In the case of as-grown silicon, no direct evidence of arsenic clusters was found by examining samples with TEM, 23 however their presence can be considered possible on the basis of sectional X-ray topography results in silicon samples doped with arsenic to a concentration of 4 × 10 19 cm-3. 24 In our case, arsenic precipitates may be formed by agglomeration of minority interstitial arsenic atoms As i that coexists with the majority substitutional species As s .…”

Section: Impact Of Heavy Donor Doping On Point Defectsmentioning

confidence: 99%

Oxygen Precipitation in Highly Doped Silicon Substrates

Porrini

Voronkov

Giannattasio

2019

ECS J. Solid State Sci. Technol.

View full text Add to dashboard Cite

This paper reviews oxygen precipitation in heavily arsenic-doped silicon. A wide arsenic concentration range is explored, from 3 × 10 18 cm −3 to 4 × 10 19 cm −3 . A precipitation retardation effect is observed in the arsenic doped samples when the dopant concentration is higher than 1.7 × 10 19 cm −3 compared with lightly doped samples having the same initial oxygen content and grown under similar conditions. The oxygen precipitate density in the heavily arsenic-doped samples is uniform along the wafer radius, with no rings or cores, contrary to what is commonly observed in lightly doped samples grown with similar V/G values. This finding is discussed by considering the role played by vacancies in the formation of oxygen precipitates and the impact of the arsenic concentration on the equilibrium concentration of point defects in silicon, deduced from the experimentally observed voids revealed as light-scattering surface defects in polished wafers.

show abstract

Electron Microscopy of As Supersaturated Silicon

Cited by 39 publications

References 14 publications

Point defects and dopant diffusion in silicon

Point defects and dopant diffusion in silicon

Contrast of small SiX particles in silicon by computed HREM images

Oxygen Precipitation in Highly Doped Silicon Substrates

Contact Info

Product

Resources

About