Mask aspects of EUVL imaging at 27nm node and below

EUVL requires the use of reflective optics including a reflective mask. The mask consists of an absorber layer pattern on top of a reflecting multilayer, tuned for 13.53 nm. The EUVL mask is a complex optical element with many parameters contributing the final wafer image quality. Specifically, the oblique incidence of light, in combination with the small ratio of wavelength to mask topography, causes a number of effects which are unique to EUV, such as an HV CD offset. These so-called shadowing effects can be corrected by means of OPC, but also need to be considered in the mask stack design. In this paper we will present an overview of the mask contributors to imaging performance at the 27 nm node and below, such as CD uniformity, multilayer and absorber stack composition, thickness and reflectivity. We will consider basic OPC and resulting MEEF and contrast. These parameters will be reviewed in the context of real-life scanner parameters both for the NXE:3100 and NXE:3300 system configurations. The predictions will be compared to exposure results on NXE:3100 tools, with NA=0.25 for different masks. Using this comparison we will extrapolate the predictions to NXE:3300, with NA=0.33. Based on the lithographic investigation, expected requirements for EUV mask parameters will be proposed for 22 nm node EUV lithography, to provide guidance for mask manufacturers to support the introduction of EUV High Volume Manufacturing.

[1]  Naoya Hayashi,et al.  Phase-shifting effect of thin-absorber EUV masks , 2011, Photomask Technology.

[2]  Osamu Suga,et al.  Thin absorber EUV mask with light-shield border of etched multilayer and its lithographic performance , 2010, Photomask Japan.

[3]  Han-Ku Cho,et al.  Properties of EUVL masks as a function of capping layer and absorber stack structures , 2007, SPIE Advanced Lithography.

[4]  Emily Gallagher,et al.  The trade-offs between thin and thick absorbers for EUV photomasks , 2011, Photomask Technology.

[5]  Johannes Ruoff Impact of mask topography and multilayer stack on high NA imaging of EUV masks , 2010, Photomask Technology.

[6]  Eelco van Setten,et al.  Impact of mask absorber on EUV imaging performance , 2010, European Mask and Lithography Conference.

[7]  Sunyoung Koo,et al.  Feasibility of EUVL thin absorber mask for minimization of mask shadowing effect , 2010, Advanced Lithography.

[8]  Natalia Davydova,et al.  Imaging performance improvements by EUV mask stack optimization , 2011, European Mask and Lithography Conference.

[9]  Tae Geun Kim,et al.  Absorber stack optimization in EUVL masks: lithographic performances in alpha demo tool and other issues , 2010, Advanced Lithography.

[10]  Natalia Davydova,et al.  EUV mask stack optimization for enhanced imaging performance , 2010, Photomask Technology.

[11]  Natalia Davydova,et al.  Holistic lithography for EUV: NXE:3100 characterization of first printed wafers using an advanced scanner model and scatterometry , 2011, Photomask Technology.

[12]  Tadahiko Takikawa,et al.  EUVL practical mask structure with light shield area for 32nm half pitch and beyond , 2008, Photomask Technology.