Abstract:
The presence of patterns can lead to temperature nonuniformity and undesirable levels of thermal stress in silicon wafers during rapid thermal processing (RTP). Plastic d...Show MoreMetadata
Abstract:
The presence of patterns can lead to temperature nonuniformity and undesirable levels of thermal stress in silicon wafers during rapid thermal processing (RTP). Plastic deformation of the wafer can lead to production problems such as photolithography overlay errors and degraded device performance. In this work, the transient temperature fields in patterned wafers are simulated using a detailed finite-element-based reactor transport model coupled with a thin film optics model for predicting the effect of patterns on the wafer radiative properties. The temperature distributions are then used to predict the stress fields in the wafer and the onset of plastic deformation. Results show that pattern-induced temperature nonuniformity can cause plastic deformation during RTP, and that the problem is exacerbated by single-side heating, increased processing temperature, and increased ramp rate. Pattern effects can be mitigated by stepping the die pattern out to the edge of the wafer or by altering the thin film stack on the wafer periphery to make the radiative properties across the wafer more uniform.
Published in: IEEE Transactions on Semiconductor Manufacturing ( Volume: 11, Issue: 1, February 1998)
DOI: 10.1109/66.661289
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1.
B. Feil, M. Drew and J. Moench, "Patterned-induced pattern misregistration after BPSG RTA reflow", Proc. 1st Int. Rapid Thermal Processing Conf., pp. 114-116, Sept. 1993.
2.
J. F. Buller, M. Farahani and S. Garg, "RTA induced overlay errors in a global alignment stepper technology", Proc. 2nd Int. Rapid Thermal Processing Conf., pp. 52-56, Aug. 31Sept. 2 1994.
3.
R. P. S. Thakur, N. Chhabra and A. Ditali, "Effects of wafer bow and warpage on the integrity of thin gate oxides", Appl. Phys. Lett., vol. 64, pp. 3428-3430, 1994.
4.
D. L. Chapek, R. A. Weimer, K. F. Scheugraf, A. Ahmad, R. P. S. Thakur and R. Singh, "Correlation between thermal stress and the performance of devices processed by RTP", Proc. 3rd Int. Rapid Thermal Processing Conf., pp. 281, Aug. 30Sept. 1 1995.
5.
J. P. Hebb and K. F. Jensen, "The effect of multilayer patterns on temperature uniformity during rapid thermal processing", J. Electrochem. Soc., vol. 143, pp. 1142-1151, 1996.
6.
P. Vandenabeele and K. Maex, "Temperature nonuniformity during rapid thermal processing of patterned wafers", Proc. SPIE, vol. 1189, pp. 89-103, 1989.
7.
J. Keuhne, S. Hattangady and M. Pas, "Effects of patterned films on the uniformity of rapid thermal oxidation", Proc. 4th Int. Rapid Thermal Processing Conf., pp. 417-420, Sept. 1996.
8.
P. Vandenabeele, K. Maex and R. De Keersmaecker, "Impact of patterned layers on temperature nonuniformity during rapid thermal processing", Mater. Res. Soc. Proc., vol. 146, pp. 149-160, 1989.
9.
M. M. Moslehi, "Process uniformity and slip dislocation patterns in linearly ramped-temperature transient rapid thermal processing of silicon", IEEE Trans. Semiconduct. Manufact., vol. 2, pp. 130-140, 1989.
10.
G. Benetini, L. Correra and C. Donolato, "Defects introduced in silicon wafers during rapid isothermal annealing: Thermoelastic and thermoplastic effects", J. Appl. Phys., vol. 56, pp. 2922-2929, 1984.
11.
H. A. Lord, "Thermal stress analysis of semiconductor wafers in a rapid thermal processing oven", IEEE Trans. Semiconduct. Dev., vol. 1, pp. 105-114, 1988.
12.
A. F. Erofeev, T. M. Makhviladze, A. V. Panjukhin, O. S. Volchek and O. Adetutu, "Simulation of thermal warpage and stress in patterned wafers during RTP", Proc. 4th Int. Rapid Thermal Processing Conf., pp. 342-346, Sept. 1996.
13.
T. P. Merchant, J. V. Cole, K. L. Knutson, J. P. Hebb and K. F. Jensen, "A systematic approach to simulating rapid thermal processing systems", J. Electrochem. Soc., vol. 143, pp. 2035-2043, 1996.
14.
P. Yeh, Optical Waves in Layered Media, 1988.
15.
P. Timans, "The effect of coatings on the emissivity of silicon", Proc. 2nd Int. Rapid Thermal Processing Conf., pp. 186-193, Aug. 31Sept. 2 1994.
16.
J. P. Hebb and K. F. Jensen, "Pattern induced temperature nonuniformity during rapid thermal processing", Proc. 4th Int. Rapid Thermal Processing Conf., pp. 34-39, Sept. 1996.
17.
E. D. Palik, Handbook of Optical Constants of Solids, 1985.
19.
M. Ohring, The Materials Science of Thin Films, 1992.
20.
H. R. Huff and R. K. Goodall, "Challenges and opportunities for dislocation free silicon wafer fabrication and thermal processing: An historical review", Proc. 3rd Int. Rapid Thermal Processing Conf., pp. 9-40, Aug. 30Sept. 1 1995.
21.
S. M. Hu, "Stress related problems in silicon technology", J. Appl. Phys., vol. 70, pp. R53-R80, 1991.
22.
L. D. Dyer, H. R. Huff and W. W. Boyd, "Plastic deformation in central regions of epitaxial silicon slices", J. Appl. Phys., vol. 42, pp. 5680-5688, 1971.
23.
W. H. Bowes, L. T. Russell and G. T. Suter, Mechanics of Engineering Materials, 1984.
24.
A. E. Widmer and W. Rehwald, "Thermoplastic deformation of silicon wafers", J. Electrochem. Soc., vol. 133, pp. 2403-2409, 1986.
25.
J. R. Patel and A. R. Chaudhuri, "Macroscopic plastic properties of dislocation-free germanium and other semiconductor crystals. I. Yield behavior", J. Appl. Phys., vol. 34, pp. 2788-2799, 1963.
26.
W. Schroter, H. G. Brion and H. Siethoff, "Yield point and dislocation mobility in silicon and germanium", J. Appl. Phys., vol. 54, pp. 1816-1820, 1983.
27.
S. P. Baker and P. H. Townsend, "Mechanical properties of thin films", Mat. Res. Soc. Fall Meeting Tutorial, 1995.
28.
P. N. Kember, S. C. Liddel and P. Blackborrow, "Characterization of plasma deposited silicon nitride as applied to novel MOS structures", Semicond. Int., vol. 8, pp. 8, 1985.
29.
E. W. Hearn, D. J. Werner and D. A. Dooney, "Film induced stress model", J. Electrochem. Soc., vol. 8, pp. 1749, 1986.
30.
J. P. Hebb, Pattern effects in rapid thermal processing, 1997.
