HF Transport Coefficients in Polymers Used for Microelectronic Applications

P. González-Aguirre; Hervé Fontaine; C. Beitia; R. Pastorello; J. Ohlsen; J. Lundgren

doi:10.4028/www.scientific.net/DDF.367.68

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HF Transport Coefficients in Polymers Used for Microelectronic Applications

Abstract:

In order to better understand the sorption and outgassing mechanism of gases in relation to wafers containers (FOUP), we have measured HF gas transport coefficients for different FOUP polymers. Gas sorption is governed by surface adsorption, followed by diffusion and solubility. Cross contamination between FOUP and wafer occurs when polymers outgas contaminants into the surrounding environment. Diffusion is the key parameter to understanding cross contamination within the FOUP environment. In this work, we present the transport coefficients obtained for gaseous HF at cleanroom conditions (Patm, 21 ± 2°C & 40% RH) using the sorption kinetic method, based on Fick’s law, for thin films (<80μm) of polycarbonate (PC), polyetherimide (PEI) and a low absorbing polymer named Entegris Barrier Material (EBM) that constitute FOUPs. The resulting kinetic curves show Fick’s behavior, where obtained HF diffusion coefficients are between 3.7 X10^-10 and 42 x10^-12 cm2/s and are significantly lower than diffusion coefficients obtained for H₂O using a gas permeation method. Nevertheless, the similar order of magnitude between the HF and the H₂O permeability coefficients obtained by the two methods validates the sorption kinetic method. Finally, the obtained coefficients were used in numerical simulation in order to forecast polymer behavior.

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Periodical:

Defect and Diffusion Forum (Volume 367)

Pages:

68-76

DOI:

https://doi.org/10.4028/www.scientific.net/DDF.367.68

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Online since:

April 2016

Authors:

P. González-Aguirre, Hervé Fontaine, C. Beitia, R. Pastorello, J. Ohlsen, J. Lundgren

Keywords:

Fick’s Law, FOUP Polymers, HF Transport Coefficients, Numerical Simulation, Sorption Kinetic

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References

[1] SEMI International Standards. F21-1102 - Classification of Airborne Molecular Contaminant Levels in Clean Environments. available at www. semi. org September (2002).

Google Scholar

[2] T. Kamoshima, Y. Fujii, T. Noguchi, T. Saeki, Y. Takata, H. Ochi, A. Koiwa. Controlling ambient gas in slot-to-slot space inside FOUP to suppress Cu-loss after dual damascene patterning, IEEE Trans. Semicon. Manufact., vol. 21.

DOI: 10.1109/tsm.2008.2005343

Google Scholar

[3] H. Fontaine, H. Feldis, A. Danel, S. Cetre, C. Ailhas. Impact of the volatile acid contaminants on Cu interconnects electrical performances ECS Transactions, 25 (5), (2009), 79-86.

DOI: 10.1149/1.3202638

Google Scholar

[4] T.Q. Nguyen, H. Fontaine, Y. Borde, V. Jacob. Identification and quantification of FOUP molecular contaminants inducing defects in integrated circuits manufacturing Microelectronic Engineering, 105, (2013), 124-129.

DOI: 10.1016/j.mee.2012.04.008

Google Scholar

[5] International Technology Roadmap for Semiconductors (ITRS), Yield Enhancement, 2013. (www. itrs. net).

Google Scholar

[6] H. Fontaine S. Cetre, M. Villerot, A. Danel. Study of the volatile organic contaminants absorption and their reversible outgassing by FOUPs Solid State Phenomena, 145-146, (2009), 143-146.

DOI: 10.4028/www.scientific.net/ssp.145-146.143

Google Scholar

[7] H. Fontaine and M. Veillerot. Plastic containers contamination by volatile acids: accumulation, release and transfer to Cu-surfaces during wafers storage Solid State Phenomena, 134, (2008), 251-254.

DOI: 10.4028/www.scientific.net/ssp.134.251

Google Scholar

[8] P. González-Aguirre, H. Fontaine, C. Beitia, J. Ohlsen, J. Lundgren, P. Lee. A comparative study of the HF sorption and outgassing ability of different Entegris FOUP platforms and materials. Microelectronic Engineering, 105 (2013), 113-188.

DOI: 10.1016/j.mee.2012.12.005

Google Scholar

[9] B. Flaconnèche, J. Martin, M.H. Klopffer, Transport Properties of Gases in Polymers : Experimental Methods. Oil & Gas Science and Tec. Vol 56, (2001) No. 3, 245-259.

DOI: 10.2516/ogst:2001022

Google Scholar

[10] H. Fontaine Y. Borde, C. Brych, A. Danel. Characterization of the HCl absorption & outgassing mechanism by FOUP's polymers. ECS Transactions, 25, 5, (2009), 139-146.

DOI: 10.1149/1.3202646

Google Scholar

[11] S. I. Moon, C. W. Extrand, Humidity Rise after Purge in Micro-Environments, Advanced Semiconductor Manufacturing Conference, (2012), 308-310.

DOI: 10.1109/asmc.2012.6212917

Google Scholar

[12] N. Santatriniaina, J. Deseure, T. Q. Nguyen, H. Fontaine, C. Beitia, L. Rakotomanana. Mathematical Modeling of the AMCs Cross-Contamination Removal in the FOUPs: Finite Element Formulation and Application in FOUP's Decontamination, International Journal of Mathematical, Computational Science and Engineering, Vol 8, No 4, (2014).

DOI: 10.14419/ijamr.v3i3.2829

Google Scholar

[13] P. González-Aguirre, H. Fontaine, C. Beitia, J. Ohlsen, J. Lundgren, P. Control of HF volatile contamination in FOUP environment by advanced polymers and clean gas purge. Solid State Phenomena Vol. 219 (2015), 247-250.

DOI: 10.4028/www.scientific.net/ssp.219.247

Google Scholar