Phase shift mask (PSM) applications are becoming essential for addressing the lithography requirements of the 65 nm technology node and beyond. Many mask writer properties must be under control to expose the second level of advanced PSM: second level alignment system accuracy, resolution, pattern fidelity, critical dimension (CD) uniformity and registration. Optical mask writers have the advantage of process simplicity for this application, as they do not require a discharge layer. This paper discusses how the mask writer properties affect the error budget for printing the second level. A deep ultraviolet (DUV) mask writer with a spatial light modulator (SLM) is used in the experimental part of the paper. Partially coherent imaging optics at the 248 nm wavelength provide improved resolution over previous systems, and pattern fidelity is optimized by a real-time corner enhancement function. Lithographic performance is compared to the requirements for second level exposure of advanced PSM. The results indicate sufficient capability and stability for 2 nd level alternating PSM patterning at the 65 nm and 45 nm nodes.
Phase shifting mask (PSM) development activity is increasing as 193nm optical lithography is extended beyond the 90nm technology node. The requirements on second level mask patterning of advanced PSM have for many applications exceeded the capability of i-line pattern generators, and it is natural for deep-ultraviolet (DUV) pattern generators to be employed for this task. The Sigma7300 DUV mask writer has the attributes required for advanced PSM applications: high resolution, tight CD uniformity and pattern placement, an accurate alignment system, and grid matching to first level exposures. The paper reports system performance for the parameters that constitute the error budget for second level patterning and shows that the mask writer is suitable for second level patterning of advanced PSMs. The alignment system employs the same laser and optics that are used for system calibration and exposure, including a CCD camera that links system calibration to alignment. As a result overlay performance is stable, and is shown to be independent of alignment mark image contrast changes due to different mask materials or resist thicknesses. The mask process uses a conventional chemically amplified resist, and does not require the use of charge dissipating top layers. Combined with throughput that is essentially independent of pattern complexity, DUV pattern generation provides a high yield solution for second level patterning of advanced PSMs for the 65nm and 45nm nodes.
With each new technology generation, photomask manufacturing faces increasing complexity due to shrinking designs and accelerating use of reticle enhancement techniques. Denser and more complex patterns on the mask result in lower yields and long write and turn-around times, important factors for the rapidly increasing mask related costs in IC manufacturing.Laser pattern generators operating at DUV wavelengths were recently introduced to provide cost effective alternatives to electron-beam systems for printing of high-end photomasks. DUV wavelengths provide the required resolution and pattern fidelity. Optical tools that use raster writing principles and massively parallel printing ensure short and predictable write times for photomasks almost independent of pattern complexity.One such high-volume production system, the Sigma7300, uses spatial light modulator (SLM) technology and a 248 nm excimer laser for printing. Partially coherent imaging and multi-pass printing as in a lithography scanner further increases resolution and pattern accuracy. With four-pass printing the system provides resolution and pattern accuracy meeting mask requirements for critical layers at the 90-nm node and sub-critical layers at the 65-nm node and beyond.The paper discusses how mask layout can be optimized to take full advantage of the speed potential provided by the SLM-based writer. It shows how flexible use of the writing principle can provide cost effective writing solutions for many layers in high-end mask sets. Resolution and pattern accuracy results from the Sigma7300 will be presented together with write times for different types of designs.
Optical proximity correction (OPC) is widely used in wafer lithography to produce a printed image that best matches the design intent while optimizing CD control. OPC software applies corrections to the mask pattern data, but in general it does not compensate for the mask writer and mask process characteristics. The Sigma7500-II deep-UV laser mask writer projects the image of a programmable spatial light modulator (SLM) using partially coherent optics similar to wafer steppers, and the optical proximity effects of the mask writer are in principle correctable with established OPC methods.To enhance mask patterning, an embedded OPC function, LinearityEqualizer™, has been developed for the Sigma7500-II that is transparent to the user and which does not degrade mask throughput. It employs a Calibre™ rule-based OPC engine from Mentor Graphics, selected for the computational speed necessary for mask run-time execution. A multinode cluster computer applies optimized table-based CD corrections to polygonized pattern data that is then fractured into an internal writer format for subsequent data processing. This embedded proximity correction flattens the linearity behavior for all linewidths and pitches, which targets to improve the CD uniformity on production photomasks.Printing results show that the CD linearity is reduced to below 5 nm for linewidths down to 200 nm, both for clear and dark and for isolated and dense features, and that sub-resolution assist features (SRAF) are reliably printed down to 120 nm. This reduction of proximity effects for main mask features and the extension of the practical resolution for SRAFs expands the application space of DUV laser mask writing.
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