Topic
Mask inspection
About: Mask inspection is a research topic. Over the lifetime, 1072 publications have been published within this topic receiving 8696 citations.
Papers published on a yearly basis
Papers
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TL;DR: DUV-based patterned mask inspection tool can meet the requirements of the pre-production EUV phase, at 32nm half-pitch, and has adequate room to extend to production at the 22nm node.
Abstract: The semiconductor industry recently concluded that EUV lithography is the most promising candidate to replace ArF for
the 22nm half-pitch node and beyond. Significant progress was made in EUV scanner and source technology and EUV
resists have achieved acceptable performance levels as well. But issues related to EUV mask inspection and defectivity
remain for the most part unanswered. This gap positions EUV masks as the leading risk to the entire technology, and
requires a robust solution during the introduction phase of EUVL. In this paper we present results from a EUV mask
inspection system. We demonstrate optimal pattern image formation by using illumination shaping, and consider
detection of various defect types that represent realistic mask defectivity scenarios. These results demonstrate that DUV-based
patterned mask inspection tool can meet the requirements of the pre-production EUV phase, at 32nm half-pitch, and has adequate room to extend to production at the 22nm node.
11 citations
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03 Nov 1994TL;DR: In this paper, a direct phase measurement system with transmitted UV-light for phase shifting mask (PSM) inspection using a shearing interferometer microscope was described, and measurements were made with 365 nm monochromatic light of mercury arc lamp.
Abstract: This paper describes a direct phase measurement system with transmitted UV-light for phase shifting mask (PSM) inspection using a shearing interferometer microscope. Measurements were made with 365 nm monochromatic light of mercury arc lamp. The accuracy of this system is sufficient for the application for phase shifting mask inspection. The measurement results are in good agreement with the calculation based on quartz step height measurement and refractive index. Wafer exposure results of attenuating-type PSM also agree with the phase measurement results.
11 citations
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TL;DR: In this paper, double patterning (DPT) is used for 45nm half-pitch or beyond and the authors evaluated the performance of DP for SE available resolution on lithography performance, pattern decomposition, and inspection load.
Abstract: Double patterning technology (DPT) is one of the most practical candidate technologies for 45nm half-pitch or beyond
while conventional single exposure (SE) is still dominant with hyper NA avoiding DPT difficulties such as split-conflict
or overlay issue. However small target dimension with hyper NA and strong illumination causes OPC difficulty and
small latitude of lithography and photomask fabricated with much tight specification are required for SE. Then there
must be double patterning (DP) approach even for SE available resolution.
In this paper DP for SE available resolution is evaluated on lithography performance, pattern decomposition, photomask
fabrication and inspection load.
DP includes pattern pitch doubled of SE, then lithography condition such as mask error enhancement factor (MEEF) is
less impacted and the lower MEEF means less tight specification for photomask fabrication.
By using Synopsys DPT software, there are no software-induced conflicts and stitching is treated to be less impact. And
also this software detects split-conflicts such as triangle or square placement from contact spacing.
For estimating photomask inspection load, programmed defect pattern and circuit pattern on binary mask are prepared.
Smaller MEEF leads less impact to defect printing which is confirmed with AIMS evaluation. As an inspection result,
there are few differences of defect sensitivity for only dense features and also few differences of false defect counts
between SE and DP with less NA. But if higher NA used, DP's inspection sensitivity is able to be lowered Then
inspection load for DP would be lighter than SE.
11 citations
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TL;DR: The RESCAN tool, a defect inspection platform being built at Paul Scherrer Institut (PSI), co-developed in collaboration with Nuflare Inc, Japan, uses Scanning Scattering Contrast Microscopy and Scanning Coherent Diffraction Imaging for fast defect detection and fine defect localization.
Abstract: With extreme ultraviolet (EUV) lithography getting ready to enter high volume manufacturing, there is an imminent need to address EUV mask metrology infrastructure. Actinic defect inspection of patterned EUV photomasks has been identified as an essential step for mask qualification, but there is no commercial tool available right now. We address this gap with the RESCAN tool, a defect inspection platform being built at Paul Scherrer Institut (PSI), co-developed in collaboration with Nuflare Inc, Japan. RESCAN uses Scanning Scattering Contrast Microscopy (SSCM) and Scanning Coherent Diffraction Imaging (SCDI) for fast defect detection and fine defect localization. The development of a stand-alone tool based on these techniques relies on the availability of (1) a bright coherent EUV source with a small footprint and (2) a high frame-rate pixel detector with extended dynamic range and high quantum efficiency for EUV. We present two in-house projects at PSI addressing the development of these components: COSAMI and JUNGFRAU. COSAMI (COmpact Source for Actinic Mask Inspection), is a high-brightness EUV source optimized for EUV photons with a relatively small footprint. JUNGFRAU (adJUstiNg Gain detector FoR the Aramis User station) is a silicon-based hybrid pixel detector, developed in house at PSI and prototyped for EUV. With a high frame rate and dynamic range at 13.5 nm, this sensor solution is an ideal candidate for the RESCAN platform. We believe that these ongoing source and sensor programs will pave the way towards a comprehensive solution for actinic patterned mask inspection bridging the gap of actinic defect detection and identification on EUV reticles.
11 citations
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04 May 2006TL;DR: In this paper, the authors present the EUV mask process with the integrated solution and the results of the mask patterning process, Ta-based in-house absorber film deposition, absorber dry etch optimization, and mask reflectivity performance.
Abstract: It becomes increasingly important to have an integrated process for Extreme UltraViolet (EUV) mask fabrication in order to meet all the requirements for the 32 nm technology node and beyond. Intel Corporation established the EUV mask pilot line by introducing EUV-specific tool sets while capitalizing on the existing photomask technology and utilizing the standard photomask equipment and processes in 2004. Since then, significant progress has been made in
many areas including absorber film deposition, mask patterning optimization, mask blank and patterned mask defect inspection, pattern defect repair, and EUV mask reflectivity metrology. In this paper we will present the EUV mask process with the integrated solution and the results of the mask patterning process, Ta-based in-house absorber film deposition, absorber dry etch optimization, EUV mask pattern defect inspection, absorber defect repair, and mask reflectivity performance. The EUV resist wafer print using the test masks that are fabricated in the EUV mask pilot line will be discussed as well.
11 citations