An Improved Approach to Accurately Model Shallow B and  BF 2 Implants in Silicon

Tasch, A.F.; Shin, Hyun Young; Park, C.; Alvis, J.; Novak, Steve

doi:10.1149/1.2096748

Cited by 84 publications

(31 citation statements)

References 11 publications

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“…The "channeled" fraction forms a long-range edge of a profile (z > 250 nm) due to the ions captured into the stable channeling at the crystal surface. For these fractions, the shapes of partial doping profiles are qualitatively similar to those of the asymmetric Pearson type IV distributions that are generally accepted in the physics of implantation and are used as basis functions w r,ch of the standard "dual Pearson" model [20].…”

Section: Problem Setupmentioning

confidence: 89%

“…Legendre [18]) polynomials, the heuristic empirical models [19][20][21] are widely used for practical calculations. To some degree, they reflect the physics of ion transport and implantation into crystals.…”

Section: Introductionmentioning

confidence: 99%

“…The models differ by a choice of w-functions. For example, within the scope of the most accepted "dual Pearson" model [20] both w r and w ch are Pearson-type distributions [22] having independent sets of parameters p r and p ch . The existing empirical models manifest a reasonable capability of fitting the doping profiles for a limited set of implantation setups (ion beam energy and direction, implantation dose).…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Enhanced phenomenological models of ion channeling contribution to doping profiles in crystals

Bratchenko¹,

Dyuldya²,

Bakai³

2009

Condens. Matter Phys.

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New phenomenological models are proposed to describe the effect of an ordered lattice structure of crystalline targets on the as-implanted doping profiles of low-energy heavy ions. The models account for the channeling kinetics and clarify the effect of bi-directional transitions of ions between random-like and channeled modes of motion on the target depth dependencies of dopant concentration. They also incorporate a simple model of the target radiation damaging effect on doping profiles. The presented results of model validation against the experimental and Monte Carlo computer simulation data and the comparative analysis of the capabilities of the proposed and the existing models show that the application of a more physically grounded approach allows us to improve the quality of doping profile description. The theoretical models developed are useful for obtaining physical parameters of low-energy ion channeling kinetics from the experimental data.

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Section: Problem Setupmentioning

confidence: 89%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Enhanced phenomenological models of ion channeling contribution to doping profiles in crystals

Bratchenko¹,

Dyuldya²,

Bakai³

2009

Condens. Matter Phys.

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“…However, according to a multiday BCA simulation using a large number of ion trajectories, values of the simulated aluminum concentration do not monotonically decrease when the aluminum concentration becomes comparable to an n-type drift-layerdoping level (in the order of 10 15 cm -3 ). A continuous-function approximation, just like the dual-Pearson approach established for ion implantation into silicon (Tasch et al, 1989), is thus needed. The historic development and basic concepts of boron diffusion in SiC are reviewed as follows.…”

Section: Introductionmentioning

confidence: 99%

One-Dimensional Models for Diffusion and Segregation of Boron and Ion Implantation of Aluminum in 4H-Silicon Carbide

Mochizuki¹

2011

Properties and Applications of Silicon Carbide

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“…The accuracy of the simulation depends on the function used. Functions to express ion implantation profiles have also been developed by using Gauss, joined half Gauss [1], Pearson [2,3], dual Pearson [4,5], and tail functions [6][7][8][9]. It has been demonstrated that the dual Pearson accurately covers the whole ion implantation profile, and it is the standard function implemented in commercial simulators [10].…”

Section: Introductionmentioning

confidence: 99%

Parameter Extraction Procedure for Ion Implantation Profiles to Establish Robust Database based on Tail Function

Suzuki¹,

Kojima²

2010

JSTS:Journal of Semiconductor Technology and Science

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Abstract-We proposed a tail function parameter extraction procedure for the establishment of a robust ion implantation database. We showed that, for the expression of ion implantation profiles, there are many local minimum values set for the third and fourth moment parameters of  and  for the Pearson function that comprises the standard dual Pearson and tail functions. We proposed the use of a joined tail function as a mediate function to extract and  , and demonstrated that this enables us to extract the parameters uniquely. Other parameters associated with channeling phenomena can also be simply and uniquely extracted by our procedure.

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An Improved Approach to Accurately Model Shallow B and BF 2 Implants in Silicon

Cited by 84 publications

References 11 publications

Enhanced phenomenological models of ion channeling contribution to doping profiles in crystals

Enhanced phenomenological models of ion channeling contribution to doping profiles in crystals

One-Dimensional Models for Diffusion and Segregation of Boron and Ion Implantation of Aluminum in 4H-Silicon Carbide

Parameter Extraction Procedure for Ion Implantation Profiles to Establish Robust Database based on Tail Function

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