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Ultra-Pure Processing: a Key Challenge for Ion Implantation Processing for Fabrication of ULSI Devices

Published online by Cambridge University Press:  21 February 2011

M. I. Current  and
L. A. Larson
M. I. Current
Affiliation:
Applied Materials, Implant Division, 3050 Bowers Avenue, Santa Clara, CA 95054 USA
L. A. Larson
Affiliation:
National Semiconductor, 2900 Semiconductor Drive, Santa Clara, CA 95052 USA
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Abstract

A key issue in modern ion implantation processing is the requirement for dramatic improvements in the purity of the incident ion beam and reductions in the deposition of foreign materials onto the wafer surface. These deposited materials include particles as well as sputtered and vapor deposited metals and dopants. Physical mechanisms which effect the elemental purity of atoms arriving at the surface of ion implanted wafers and progress towards achieving implantation purity levels of below 100 ppm of the implanted dose for sputtered metal and dopant films are discussed.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 147: Symposium C – Ion Beam Processing of Advanced Electronic Materials , 1989 , 365
Copyright
Copyright © Materials Research Society 1989

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References

1) For example, see the Proc. 7 th Int. Conf. on Ion Implantation Technology, Kyoto (June, 1988), Nuc. Inst. Meth. B37/38(1989).Google Scholar
2) Ohmi, T., Mikoshiba, M. and Tsubouchi, K., “Super Clean Room System- Ultra Clean Technology for Submicron LSI Fabrication”, in ULSI Science and Technology/1987, Electrochemical Society Proceedings 87–11 (1987) 761785.Google Scholar
3) Oberai, A. S, “Lithography-Challenges of the Future”, Solid State Technology, Vol.30, No. 9 (Sept. 1987) 123128. Google Scholar
4) Forneris, J.L. et al., “Implant Processes for Bipolar Product Manufacturing and Their Effects on Device Yield” in Ion Implantation: Equipment and Techniques, eds. Ryssel, H. and Glawischnig, H., Springer (1983) pp. 407425.Google Scholar
5) Smith, T.C., “Photoresist Problems and Particle Contamination”, in Ion Implantation Science and Technology, 2nd Edition, ed. Ziegler, J.F., Academic Press (1988) pp. 345375.Google Scholar
6) Weisenberger, W., Borden, P. and Knodle, W., “Real-time In-situ Particle Monitoring in a High Current Ion Implantation Production Bay”, to appear in Nuc. Inst. Meth. B37/38(1989).Google Scholar
7) Strain, J., Moffatt, S. and Current, M., “Characterization and Reduction of Particle Contamination in Ion Implantation Processing”, in Microcontamination/88, Santa Clara, CA (1988) 4254.Google Scholar
8) Haas, E.W., Glawischnig, H., Lichti, G. and Bleier, A., “Activation Analysis of Contamination and Cross-Contamination in Ion Implantation”, J. of Electronic Materials, 7 (1978) 525533.Google Scholar
9) Masters, B.J., “RadioTracer Measurements of Sputtered Contamination Incurred During Ion Implantation Processing, IEEE Trans. Nucl. Sci. NS–20 (1973) 10321034.Google Scholar
10) Hemment, P.L.F., ldquo;Sample Contamination Caused by Sputtering During Ion Implantation”, Vacuum 29 (1979) 439442.Google Scholar
11) Larson, L.A. and Current, M.I., “Metallic Impurities and Dopant Cross- Contamination Effects in Ion Implanted Surfaces”, in Materials Research Society Proceedings, 45 (1985) 381388.Google Scholar
12) Larson, L.A., Current, M.I. and Healy, C., “Enhanced Diffusion Effects and Dopant Cross-Contamination in Ion Implanted Surfaces”, in Semiconductor Silicon 1986, Electrochemical Society Proceedings 86–4 (1986)667675.Google Scholar
13) Sadana, D.K., Wu, N.R., Washburn, J., Current, M.I., Morgan, A., Reed, D., Maenpaa, M., “The Effect of Recoiled Oxygen on Damage Regrowth and Electrical Properties of Through-Oxide Implanted Silicon” Nuc. Inst. Meth 209/210(1983)743750.Google Scholar
14) Kennedy, G.L. and Larson, L.A., “An Examination of Implant Cross- Contamination Levels Produced by Clampless Disks” J. Electrochem Soc. 135(1988)18051808.Google Scholar
15) Steen, L.S., Hall, J.M., Aitken, D.A., Plumb, F.G., Wauk, M.T., Bright, N., Pruitt, C., Robinson, L., “The Precision Implant 9000, A New Concept in Ion Implantation Systems”, Nuc. Inst. Meth B21(1987)328333.Google Scholar
16) Moffatt, S.,” A 100 mA Class Ion Implanter for Large Scale Production of Buried Oxide SO Wafers”, Nuc. Inst. Meth B21 (1987)251257.Google Scholar
17) Fair., R.B., “Concentration Profiles of Diffused Dopants in Silicon”, in Impurity Doping Processes in Silicon, ed. Wang, F.F.Y., North- Holland (1981)pp. 315442.Google Scholar
18) Simard-Normandin, M. and Slaby, C., J. Electrochem. Soc. 132 (1985)22182223.Google Scholar
19) Wilson, R.G, J. Appl. Physics 54 (1983) 68796889.Google Scholar
20) Holland, O.W., Alvis, J.R. and Hance, C.,SPIE Proc. 797 (1987) 1419.Google Scholar
21) Tung, N. Chan, J. Electrochem. Soc. 132 (1985)914917.Google Scholar
22) Nieh, C.W. and Chen, L.J.; J. Appl. Physics 60 (1986)3114 and Appl. Phys. Lett. 48 (1986) 1528.Google Scholar
23) Teng, K.W., Tseng, H.H., Nguyen, B.Y. and Lou, F.T., Electrochem. Soc. Extended Abstracts 87–1 (1987) 328329.Google Scholar
24) Mazure, C., Winnerl, J. and Neppl, F.,Solid State Device Research Conf. (Bologna, 1987) pg. 585–588.Google Scholar