Atomistic Modeling of Point and Extended Defects in Crystalline Materials

Martin Jaraiz; Lourdes Pelaz; Emiliano Rubio; Juan Barbolla; George H. Gilmer; David J. Eaglesham; Hans J. Gossmann; John M. Poate

doi:10.1557/PROC-532-43

Abstract

Atomistic process modeling, a kinetic Monte Carlo simulation technique, has the interest of being both conceptually simple and extremely powerful. Instead of reaction equations it is based on the definition of the interactions between individual atoms and defects. Those interactions can be derived either directly from molecular dynamics or first principles calculations, or from experiments. The limit to its use is set by the size dimensions it can handle, but the level of performance achieved by even workstations and PC's, together with the design of efficient simulation schemes, has revealed it as a good candidate for building the next generation of process simulators, as an extension of existing continuum modeling codes into the deep submicron size regime. Over the last few years it has provided a unique insight into the atomistic mechanisms of defect formation and dopant diffusion during ion implantation and annealing in silicon. Object-oriented programming can be very helpful in cutting software development time, but care has to be taken not to degrade performance in the critical inner calculation loops. We discuss these techniques and results with the help of a fast object-oriented atomistic simulator recently developed.

References

REFERENCES

1. Hockney, R. W. and Eastwood, J. W., Computer simulation using particles, Adam Hilger, New York, 1988, p. 19.Google Scholar

2. Muroga, T. and Ishino, s., J. Nucl. Mat. 117, p.36 (1983).Google Scholar

3. Heinisch, H. L., Nucl. Instr. Meth. B 102, p. 47 (1995).Google Scholar

4. Jaraiz, M., Gilmer, G. H., Poate, J. M. and de la Rubia, T. D., Appl. Phys. Lett. 68, p. 409 (1996).Google Scholar

5. Pelaz, L., Jaraiz, M., Gilmer, G. H., Rafferty, C. S., Eaglesham, D. J. and Poate, J. M., Appl. Phys. Lett. 70, p. 2285 (1997).Google Scholar

6. Takeda, S., Jpn. J. Appl. Phys. 30, L639 (1991).Google Scholar

7. Holland, O. W. and White, C. W., Nucl. Instr. Meth. B 59/60, p. 353 (1991).Google Scholar

8. Stolk, P. A., Gossmann, H. J., Eaglesham, D. J. and Poate, J. M., Nucl. Instr. Meth. B 96, p. 187 (1995).Google Scholar

9. Agarwal, A., Haynes, T. E., Eaglesham, D. J., Gossmann, H. J., Jacobson, D. C., Poate, J. M. and Erokhin, Y. E., Appl. Phys. Lett. 70, p. 3332 (1997).Google Scholar

10. Lyu, J., Park, B.-G., Chun, K. and Lee, J. D., IEEE Electron Device Lett. 18, p. 535 (1997).Google Scholar

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Pelaz, Lourdes Gilmer, G. H. Venezia, V. C. Gossmann, H.-J. Jaraiz, M. and Barbolla, J. 1999. Modeling of the effects of dose, dose rate, and implant temperature on transient enhanced diffusion. Applied Physics Letters, Vol. 74, Issue. 14, p. 2017.

Cowern, N.E.B Mannino, G Stolk, P.A Roozeboom, F Huizing, H.G.A van Berkum, J.G.M Cristiano, F Claverie, A and Jaraı́z, M 1999. Cluster ripening and transient enhanced diffusion in silicon. Materials Science in Semiconductor Processing, Vol. 2, Issue. 4, p. 369.

Cowern, N. E. B. Mannino, G. Stolk, P. A. Roozeboom, F. Huizing, H. G. A. van Berkum, J. G. M. Cristiano, F. Claverie, A. and Jaraíz, M. 1999. Energetics of Self-Interstitial Clusters in Si. Physical Review Letters, Vol. 82, Issue. 22, p. 4460.

Cowern, N.E.B. Mannino, G. Stolk, P.A. and Theunissen, M.J.J. 1999. Defects and Diffusion in Silicon: An Overview. MRS Proceedings, Vol. 568, Issue. ,

Venezia, V. C. Haynes, T. E. Agarwal, Aditya Pelaz, L. Gossmann, H.-J. Jacobson, D. C. and Eaglesham, D. J. 1999. Mechanism for the reduction of interstitial supersaturations in MeV-implanted silicon. Applied Physics Letters, Vol. 74, Issue. 9, p. 1299.

Cowern, N.E.B. Jaraiz, M. Cristiano, F. Claverie, A. and Mannino, G. 1999. Fundamental diffusion issues for deep-submicron device processing. p. 333.

Pelaz, Lourdes Gilmer, G. H. Gossmann, H.-J. Rafferty, C. S. Jaraiz, M. and Barbolla, J. 1999. B cluster formation and dissolution in Si: A scenario based on atomistic modeling. Applied Physics Letters, Vol. 74, Issue. 24, p. 3657.

Jaraiz, M Rubio, E Castrillo, P Pelaz, L Bailon, L Barbolla, J Gilmer, G.H and Rafferty, C.S 2000. Kinetic Monte Carlo simulations: an accurate bridge between ab initio calculations and standard process experimental data. Materials Science in Semiconductor Processing, Vol. 3, Issue. 1-2, p. 59.

Pinachoa, R. Jaraíz, M. Gossmann, H. J. Gilmer, G. H. Benton, J. L. and Werner, P. 2000. The Effect of Carbon/Self-Interstitial Clusters on Carbon Diffusion in Silicon Modeled by Kinetic Monte Carlo Simulations. MRS Proceedings, Vol. 610, Issue. ,

Jaraiz, Martin Castrillo, Pedro Pinacho, Ruth Pelaz, Lourdes Barbolla, Juan Gilmer, George H. and Rafferty, Conor S. 2000. Atomistic Modeling of Complex Silicon Processing Scenarios. MRS Proceedings, Vol. 610, Issue. ,

Colombeau, B. Cristiano, F. Marrot, J-C. Assayag, G. Ben and Claverie, A. 2001. Effect of the Ge preamorphisation dose on the thermal evolution of End of Range defects. MRS Proceedings, Vol. 669, Issue. ,

Min Yu Ru Huang and Xing Zhang 2001. Atomistic annealing simulation: kinetic lattice Monte Carlo. Vol. 2, Issue. , p. 909.

Min Yu Ru Huang Xing Zhang Yangyuan Wang and Oka, H. 2002. Atomistic simulation of RTA annealing for shallow junction formation characterizing both BED and TED. p. 123.

Martin-Bragado, I. Jaraiz, M. Castrillo, P. Pinacho, R. Barbolla, J. and De Souza, M. M. 2003. Mobile silicon di-interstitial: Surface, self-interstitial clustering, and transient enhanced diffusion phenomena. Physical Review B, Vol. 68, Issue. 19,

Hobler, G. and Otto, G. 2003. Status and open problems in modeling of as-implanted damage in silicon. Materials Science in Semiconductor Processing, Vol. 6, Issue. 1-3, p. 1.

Aboy, Maria Pelaz, Lourdes Marqués, Luis A. Enriquez, L. and Barbolla, Juan 2003. Atomistic analysis of defect evolution and transient enhanced diffusion in silicon. Journal of Applied Physics, Vol. 94, Issue. 2, p. 1013.

Aboy, M. Pelaz, L. Marques, L.A. Barbolla, J. Mokhberi, A. Takamura, Y. Griffin, P.B. and Plummer, J.D. 2003. Atomistic modeling of B activation and deactivation for ultra-shallow junction formation. p. 151.

Aboy, Maria Pelaz, Lourdes Marqués, Luis A. Barbolla, Juan Mokhberi, Ali Takamura, Yayoi Griffin, Peter B. and Plummer, James D. 2003. Atomistic modeling of deactivation and reactivation mechanisms in high-concentration boron profiles. Applied Physics Letters, Vol. 83, Issue. 20, p. 4166.

Ohseob Kwon Kidong Kim Jihyun Seo Chiok Hwang and Taeyoung Won 2003. Process and device simulation based on atomistic and quantum mechanical approach in the regime of sub-50 nm gate length. p. 244.

Venezia, V.C. Duffy, R. Pelaz, L. Aboy, M. Heringa, A. Griffin, P.B. Wang, C.C. Hopstaken, M.J.P. Tamminga, Y. Dao, T. Pawlak, B. and Roozeboom, F. 2003. Dopant redistribution effects in preamorphized silicon during low temperature annealing. p. 20.3.1.

Download full list

Article contents

Atomistic Modeling of Point and Extended Defects in Crystalline Materials

Abstract

Access options

References

REFERENCES

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

Atomistic Modeling of Point and Extended Defects in Crystalline Materials

Abstract

Access options

References

REFERENCES

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests