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Gaseous spectral filters to mitigate infrared radiation

Gas molecules that absorb infrared photons can reduce the incidence of out-of-band radiation at 10.6μm in extreme ultraviolet exposure tools that use a carbon dioxide drive laser.
18 February 2011, SPIE Newsroom. DOI: 10.1117/2.1201101.003424

Extreme ultraviolet (EUV) lithography is a promising technology to print features 22nm in dimension or less for the semiconductor industry.1–4 To generate the EUV light (13.5nm wavelength) needed for this technology, a leading technique uses an infrared carbon dioxide (CO2) laser pulse to ionize a target to produce a plasma.4,5 The spectrum of this laser-produced plasma is dominated by infrared radiation from the CO2 drive laser (10.6μm wavelength).6 Of this infrared radiation incident on the collector optics, over 90% is reflected5 towards the intermediate focus—the exit point for the light generated in the EUV source region. An issue with this technique is that infrared radiation heating causes thermal deformation of the optical components beyond the intermediate focus.6 Therefore, in EUV systems that include a CO2 laser-produced plasma, spectral filters that can withstand high-heat loads with minimal EUV transmission loss are needed to mitigate 10.6μm infrared radiation.

Recent proposals to tackle the reduction of the unwanted radiation included a grid filter, a low-infrared reflecting mirror, and a blazed-reflection grating.6–8 These structures show remarkable suppression of the infrared radiation at the intermediate focus. But EUV transmission loss resultant from their use continues to be a critical concern in these photon-limited exposure tools.

We are developing a system that uses an infrared absorbing gas to target the mitigation of the unwanted CO2 laser light. A continuous flow of the gas across the path of the incident light absorbs the infrared photons at 10.6μm wavelength: see Figure 1. Heat-load concerns and manufacturing inconsistencies, which affect some spectral filters, are largely avoided with this method.

Figure 1. Configuration of CO2 laser-produced plasma source with focusing collector mirrors and possible location of the infrared absorbing gas.

Our work focuses on measuring the infrared absorption of gases with infrared-active vibrational modes that coincide with CO2 laser lines near 10.6μm: see Table 1. The ultimate goal is to maximize the absorption of infrared radiation with minimum EUV absorption. One gas of interest is sulfur hexafluoride (SF6), which has an infrared active υ3 vibrational mode that is resonantly excited by photons from the laser lines in Table 1.9 The infrared molecular excitation at each wavelength indicated is due to quantized transitions in the fundamental υ3 band of SF6.

Production of radical SF6 fragments due to the incidence of high-energy EUV photons (92eV per photon) in the immediate vicinity of the optics may be undesirable due to potential damage. To address this concern, a method must be adapted to confine the interaction region of the SF6 gas molecules and the incident radiation, while maintaining minimal EUV transmission losses. One possibility uses a jet of an inert gas to prevent SF6 molecules from entering into the optics chamber. Inert gases such as helium, neon, and argon show greater than 90% EUV transmission10 and so are attractive options for this purpose. An improvement to this method uses a low-density plasma of the inert gas jet to enhance the confinement achieved. The use of a stabilized short-plasma arc to provide an obstruction to gas flow without any interfering solid structures has been demonstrated previously.11–13 This apparatus, known as a plasma window, has been used to separate two regions of different pressure, while allowing particle beams and radiation to be transmitted.

Hundreds of watts of infrared power are expected at the intermediate focus.6 Estimating what fraction of the heat energy can be dissipated by the infrared absorbing gas is critical to our research. Multiphoton absorption effects in SF6, especially in the presence of buffer gases, may enhance the expected number of infrared photons absorbed.9,14,15 The rate of collisional-relaxation processes following photon absorption by SF6 molecules plays a vital role in avoiding saturation.

Table 1. CO2 laser wavelengths (λ) near 10.6μm.9P(X): The laser line originates from a quantized transition from vibrational sublevel X-1 to sublevel X.
CO2 laser lineλ(μm)Wavenumber (cm−1)

A strategy to use an infrared absorbing gas to reduce the infrared radiation from CO2 laser-produced plasma sources used for EUV lithography is promising. Preliminary experiments have confirmed the significant absorption of SF6 across the CO2 laser wavelengths compared to EUV light. Mass spectrometer measurements reveal that an argon plasma has a slightly better obstruction to the diffusion of SF6 molecules than an argon-gas jet. In the future, we will focus on the design specifications of the spectral filter that will use an infrared absorbing gas to mitigate radiation at 10.6μm in CO2 laser-produced plasma EUV exposure tools.

Chimaobi Mbanaso, Gregory Denbeaux, Alin Antohe
College of Nanoscale Science and Engineering, State University of New York
Albany, NY

Frank Goodwin
Albany, NY

Ady Hershcovitch
Brookhaven National Laboratory
Upton, NY 

1. V. Bakshi ed., EUV Lithography, SPIE Press, 2008.
2. V. Bakshi ed., EUV Sources for Lithography, SPIE Press, 2006.
3. K. Kemp and S. Wurm, EUV lithography, C.R. Physique 7, pp. 875-886, 2006. doi:10.1016/j.crhy.2006.10.002
4. Y. Tao, M. S. Tillack, S. Yuspeh, R. A. Burdt, N. M. Shaikh, N. Amin, F. Najmabadi, Interaction of a CO2 laser pulse with tin-based plasma for an extreme ultraviolet lithography source, IEEE Trans. Plasma Sci. 38, pp. 714-718, 2010.
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6. W. A. Soer, M. J. J. Jak, M. M. J. W. van Herpen, A. M. Yakunin, V. Y. Banine, Grid Spectral Purity Filters for Suppression of Infrared Radiation in Laser- Produced Plasma EUV Sources, Proc. SPIE 7271, 2009. doi:10.1117/12.814231
7. W. A. Soer, P. Gawlitza, M. M. J. W. van Herpen, M. J. J. Jak, S. Braun, P. Muys, V. Y. Banine, Extreme ultraviolet multilayer mirror with near-zero IR reflectance, Opt. Lett. 34, pp. 3680-3682, 2009. doi:10.1364/OL.34.003680
8. A. J. R. van den Boogaard, E. Louis, F. A. van Goor, and F. Bijkerk, Optical element for full spectral purity from IR-generated EUV light sources, Proc. SPIE 7271, 2009. doi:10.1117/12.829011
9. C. D. Cantrell ed., Multiple-Photon Excitation and Dissociation of Polyatomic Molecules, Springer Topics in Current Physics 35, Springer-Verlag, 1986.
10. Center for X-Ray Optics:http://henke.lbl.gov/optical_constants/
11. A. Hershcovitch, A plasma window for the trnasmission of particle beams and radiation from vacuum to atmosphere for various applications, Phys. Plasmas 5, pp. 2130-2136, 1998. doi:10.1063/1.872885
12. D. Salerno, B. T. Pinkoski, A. Hershcovitch, E. Johnson, Windowless targets for intense beams,  Nucl. Instrum. Methods Phys. Res. A 469, pp. 13-20, 2001. doi:10.1016/S0168-9002(01)00707-0
13. B. T. Pinkoski, I. Zacharia, A. Hershcovitch, E. D. Johnson, D. P. Siddons, X-ray transmission through a plasma window, Rev. Sci. Instrum. 72, pp. 1677-1679, 2001. doi:10.1063/1.1344598
14. J. Jovanovic-Kurepa, D. D. Markusev, M. Terzic, Multiple absorption and relaxation processes in SF6–CH4 mixtures: an experimental study, Chem. Phys. 211, pp. 347-358, 1996. doi:10.1016/0301-0104(96)00156-5
15. D. D. Markushev, J. Jovanovic-Kurepa, M. Terzic, Excitation dynamics during the multiphoton absorption in SF6+buffer-gas mixtures, J. Quant. Spectrosc. Radiat. Transfer 76, pp. 85-99, 2003. doi:10.1016/S0022-4073(02)00047-X