Your search keyword '"Braatz, R. D."' showing total 6 results

1. Controlling Dopant Diffusion and Activation through Surface Chemistry.

Author

Dev, K., Kwok, C. T. M., Vaidyanathan, R., Braatz, R. D., and Seebauer, E. G.

Subjects

DIFFUSION, ACTIVATION (Chemistry), SURFACE chemistry, ION implantation, POINT defects, SEMICONDUCTOR junctions, BORON, ARSENIC

Abstract

The degree of chemical bond saturation at surfaces can affect dopant activation and transient enhanced diffusion (TED) in silicon during annealing for ultrashallow junction formation. Point defects such as interstitial atoms can more easily combine with unsaturated dangling bonds than with saturated ones. Thus, maintaining an atomically clean surface during annealing greatly increases the annihilation probability. Statistical arguments show that such a surface removes Si interstitials from the underlying solid much faster than dopant interstitials. Simulations for boron and experiments for arsenic show that this effect leads to large and simultaneous improvements in dopant activation and TED. This surface-based method of defect engineering is relatively easy to integrate into a process line, and offers benefits over and above what can be obtained with methods used in parallel such as carbon co-implantation and laser annealing. © 2006 American Institute of Physics [ABSTRACT FROM AUTHOR]

Published

2006

2. Robustness analysis of multivariable systems with time delays.

Author

Gunawan, R., Russell, E. L., and Braatz, R. D.

Published

2001

3. Worst-case performance analysis of optimal batch control trajectories.

Author

Ma, D. L., Chung, S. H., and Braatz, R. D.

Published

1999

4. μ-sensitivities as an aid for robust identification.

Author

Braatz, R. D. and Morari, M.

Published

1991

5. Pair Diffusion and Kick-out: Contributions to Diffusion of Boron in Silicon.

Author

Jung, M. Y. L., Gunawan, R., Braatz, R. D., and Seebauer, E. G.

Subjects

DIFFUSION, BORON, SILICON, MICROELECTRONICS, MULTIVARIATE analysis, MONTE Carlo method

Abstract

Diffusion of boron in silicon has great technological relevance to microelectronic processing. Despite considerable effort spanning over many years, the dominant mechanism for this diffusion remains strongly debated, together with the values of key activation energies. Some evidence indicates that the principal mobile species is a B-Si complex (so-called "pair diffusion"), whereas other evidence points to a lone boron interstitial ("kick-out"). An attempt to resolve the question is made by formulating a comprehensive kinetic model that incorporates both mechanisms. Rate parameters for the elementary steps are estimated systematically, based on literature reports or physical arguments. In the frequent cases where reports conflict, maximum likelihood estimation is employed to determine the best value, and multivariate statistics to quantify its accuracy. A Monte Carlo technique is used to show that kick-out very likely dominates pair diffusion in both implanted Si and unimplanted silicon. [ABSTRACT FROM AUTHOR]

Published

2004

6. Maximum A posteriori estimation of transient enhanced diffusion energetics.

Author

Gunawan, R., Jung, M. Y. L., Seebauer, E. G., and Braatz, R. D.

Published

2003