Mask inspection

About: Mask inspection is a research topic. Over the lifetime, 1072 publications have been published within this topic receiving 8696 citations.

Mask inspection device

Abstract: PROBLEM TO BE SOLVED: To perform automatic inspection with high speed by providing a photodetecting means and a moving means which are provided with a light source and a photomask in between and detects the light that the opening part of the photomask transmits, and a judging means which compares the output of the photodetecting means with a reference value. SOLUTION: A light source 1 illuminates a photomask 5 uniformly. On an X-Y stage 3, a photodetector 2 disposed near the photomask 5 is mounted, and it scans the photomask 5. A signal processing circuit 4 amplifies the output signal of the photodetector 2, shapes the waveform of the signal, and compares it with a reference value set in advance. By this, whether good or bad of the photomask 5 is judged, and the judgment result is displayed on a monitor 11.

Wavelength dependent spot defects on advanced embedded attenuated phase-shift masks

Abstract: At the challenging ground rules required for 90 nm and 65 nm photomask production, new types of photomask defects are becoming increasingly prevalent. This paper discusses one particular new defect type found on critical 90 nm embedded attenuated phase-shift masks (EAPSMs). These defects had varying transmission characteristics depending on the wavelength used for analysis. Given that photomask inspection wavelength has historically lagged behind lithography wavelength, this type of defect can go undetected and poses a grave risk to wafer lithography yield. Detection and characterization methodologies will be presented along with aerial image analysis and wafer print evaluation results.

Photomask inspection method

Abstract: A photomask inspection method that identifies a foreign particle such as dirt on a photomask with high sensitivity by suppressing erroneous identification due to an influence of noise is provided. The photomask inspection method includes acquiring image data of a photomask having regions with different layer structures on a surface thereof, creating inverted image data by subtracting the image data from pixel value data of the regions, creating offset inverted image data by raising pixel values of the inverted image data by a fixed amount, creating normalized correlation image data by computing a normalized correlation of the offset inverted image data and an offset Gaussian distribution-type kernel, and identifying foreign particles by comparing the normalized correlation image data and a predetermined threshold.

Capability of particle inspection on patterned EUV mask using model EBEYE M

Abstract: According to the road map shown in ITRS [1], the EUV mask requirement for defect inspection is to detect the defect size of sub- 20 nm in the near future. EB (Electron Beam) inspection with high resolution is one of the promising candidates to meet such severe defect inspection requirements. However, conventional EB inspection using the SEM method has the problem of low throughput. Therefore, we have developed an EB inspection tool, named Model EBEYE M※. The tool has the PEM (Projection Electron Microscope) technique and the image acquisition technique with TDI (Time Delay Integration) sensor while moving the stage continuously to achieve high throughput [2]. In our previous study, we showed the performance of the tool applied for the half pitch (hp) 2X nm node in a production phase for particle inspection on an EUV blank. In the study, the sensitivity of 20 nm with capture rate of 100 % and the throughput of 1 hour per 100 mm square were achieved, which was higher than the conventional optical inspection tool for EUV mask inspection [3]-[5]. Such particle inspection is called for not only on the EUV blank but also on the patterned EUV mask. It is required after defect repair and final cleaning for EUV mask fabrication. Moreover, it is useful as a particle monitoring tool between a certain numbers of exposures for wafer fabrication because EUV pellicle has not been ready yet. However, since the patterned EUV mask consists of 3D structure, it is more difficult than that on the EUV blank. In this paper, we evaluated that the particle inspection on the EUV blank using the tool which was applied for the patterned EUV mask. Moreover, the capability of the particle inspection on the patterned EUV mask for the hp 2X nm node, whose target is 25 nm of the sensitivity, was confirmed. As a result, the inspection and SEM review results of the patterned EUV masks revealed that the sensitivity of the hp 100 nm Line/Space (LS) was 25 nm and that of the hp 140- 160 nm Contact Hole (CH) was 21 nm. Therefore, we confirmed that particle inspection on the patterned EUV mask using Model EBEYE M could be available for the EUV mask of the hp 2X nm node. In the future, we will try to inspect the production mask of the hp 2X nm node, and try to confirm the performance for the EUV mask of the hp 1X nm node.

High-radiance LDP source for mask inspection and beam line applications (Conference Presentation)

Abstract: High-throughput actinic mask inspection tools are needed as EUVL begins to enter into volume production phase. One of the key technologies to realize such inspection tools is a high-radiance EUV source of which radiance is supposed to be as high as 100 W/mm2/sr. Ushio is developing laser-assisted discharge-produced plasma (LDP) sources. Ushio’s LDP source is able to provide sufficient radiance as well as cleanliness, stability and reliability. Radiance behind the debris mitigation system was confirmed to be 120 W/mm2/sr at 9 kHz and peak radiance at the plasma was increased to over 200 W/mm2/sr in the recent development which supports high-throughput, high-precision mask inspection in the current and future technology nodes. One of the unique features of Ushio’s LDP source is cleanliness. Cleanliness evaluation using both grazing-incidence Ru mirrors and normal-incidence Mo/Si mirrors showed no considerable damage to the mirrors other than smooth sputtering of the surface at the pace of a few nm per Gpulse. In order to prove the system reliability, several long-term tests were performed. Data recorded during the tests was analyzed to assess two-dimensional radiance stability. In addition, several operating parameters were monitored to figure out which contributes to the radiance stability. The latest model that features a large opening angle was recently developed so that the tool can utilize a large number of debris-free photons behind the debris shield. The model was designed both for beam line application and high-throughput mask inspection application. At the time of publication, the first product is supposed to be in use at the customer site.