In the continuous drive for smaller feature sizes, process monitoring becomes increasingly important to compensate for the smaller lithography process window and to assure that Critical Dimensions (CD) remain within the required specifications. Moreover, the higher level of automation in manufacturing enables almost real-time correction of lithography cluster machine parameters, resulting in a more efficient and controlled use of the tools. Therefore, fast and precise in-line lithography metrology using Advanced Process Control (APC) rules are becoming crucial, in order to guarantee that critical dimensions stay correctly targeted. In this paper, the feasibility of improving the CD control of a 193nm lithography cluster has been investigated by using integrated scatterometry. The target of the work was to identify if a dose correction on field and wafer level, based on precise in-line measurements, could improve the overall CD control. Firstly, the integrated metrology has been evaluated extensively towards precision and sensitivity in order to prove its benefits for this kind of control. Having a long-term repeatability of significantly better than 0.75nm 3σ, this was very promising towards the requirements for subnanometer CD correction. Moreover, based on an extensive evaluation of the process window on the lithography cluster, it has been shown that the focus variation is minimal and that CD control can be improved using dose correction only. In addition, systematic variations in across-wafer uniformity and across-lot uniformity have been determined during this monitoring period, in order to identify correctable fingerprints. Finally, the dose correction model has been applied to compensate for these systematic CD variations and improved CD control was demonstrated. Using a simple dose correction rule, a forty percent improvement in CD control was obtained.
Gate patterning is critical to the final yield and performance of logic devices. Because of this, gate linewidth control is viewed by many as the most critical application for integrated metrology on etch systems. For several years, integrated metrology and wafer-level process control have been used in high volume manufacturing of 90 and 65nm polysilicon gate etch [1], [3], [17], [22]. These wafer-level CD control systems have shown the ability to significantly reduce CD variation. With gate linewidth under control (< 2nm 3σ wafer-to-wafer), the next parameter to impact gate electrical performance is side wall angle (SWA). SWA had not been considered a critical control parameter due to the difficulty of measurement with conventional scanning electron microscope (SEM). With scatterometry, SWA measurement of litho and etch profiles are included with the critical dimension (CD) measurements. Recently, it has become visible that the polysilicon SWA correlates to electrical device parameters, and is thus, an important parameter to control. This paper will examine the current relationship between litho and etch profile control, determine potential limitations for future technology nodes, and introduce novel etch process control techniques based on multiple input multiple output (MIMO) modeling.
A series of experiments were performed to determine if the ThermaWave INTEGRA TM CCDi reflectometer combined with Timbre Technologies' Optical Digital Profiler TM (ODP) software could meet the requirements for lithography cell integration and process control of critical 0.13-micron Flash memory applications. Shallow Trench Isolation (STI), First Poly Gate, Stacked Gate and Aluminum Interconnect layers were examined as a part of this study. ODP models were developed for each of these applications and their output was compared to Critical Dimension Scanning Electron Microscopy (CDSEM) and cross-section SEM to demonstrate adequate correlation to incumbent metrology techniques. ODP is shown herein to correlate to CDSEM while providing the throughput required to measure every wafer without creating a bottleneck for the lithography cell. Experimental results also suggest that, in many cases, ODP can deliver profile determination beyond the fundamental capability of standard in-line metrology techniques.
Scatterometry has been most commonly applied to CD metrology of line/space grating structures. However, for the process development and control of 3D structures for contact hole lithography applications, the current metrology methods of CD-SEM, electrical CD (ECD) and/or cross-sectional SEM (X-SEM) produce the desired information either (a) as an incomplete solution, (b) too late in process flow, or (c) in a destructive manner. In this paper, we will present use cases for the application of scatterometry to 3D structures, i.e., post-lithography hole/space patterns, where measurements of CD, profile, and film thickness can be made immediately following the lithography process, in a method nondestructive to the wafer. These use cases demonstrate the capability of 3D metrology integrated onto a TEL Clean Track platform, where a Therma-Wave reflectometer was used to generate spectra that were then processed via Timbre ODP, for a film stack of patterned photoresist (PR), anti-reflective coating (ARC), and oxide on top of a silicon (Si) substrate. Focus-Exposure Matrix (FEM) wafers have also been produced in order to characterize the contact hole profile and CD variation as a result of changing focus and exposure conditions. The results of the experiment show that ODP can be used successfully to monitor CD, film thickness, and profile variation, providing a valuable solution to contact hole lithography. Tool precision and matching results are also shown, which indicate the stability of the measurement process, and correlation to CD-SEM is also provided as a reference metrology. These results suggest that integrated 3D scatterometry is a viable production metrology solution, enabling the progression toward Advanced Process Control (APC). Downloaded From: http://proceedings.spiedigitallibrary.org/ on 06/21/2016 Terms of Use: http://spiedigitallibrary.org/ss/TermsOfUse.aspxFigure 2. Longterm repeatability measurements of resist middle diameter were taken over a nine-day period. Results show that the maximum 3σ over all five measured sites was 0.47nm. 90nm Node Contact Litho Longterm repeatability: Max 3σ = 0.47nm
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