Anja Rosenbusch

Aerial-image-based inspection on subresolution scattering bars

The paper presents the results of a study to define a production-worthy inspection technique for subresolution solid and hollow scattering features used in 193-nm lithography. Masks are inspected using conventional high-NA and aerial-imaging-based mask inspection tools. Inspection results are compared regarding capture rate and nuisance defect rate.

Aerial image-based inspection of binary (OPC) and embedded-attenuated PSM

The paper presents a revolutionary technology to inspect advanced contact layers. Instead of finding defects based on a size-dependent defect specification, defects are found according to their impact at the wafer CD result. The inspection methodology used is aerial imaging. The main advantage of this method is that only defects, which actually affect the wafer result, will be detected and classified. The paper presents first inspection results on contact layers designed for the 130nm and 90 nm technology node.

Defect dispositioning using mask printability on attenuated phase shift production photomasks

This paper examines the effects of mask printability of various OPC defect types on a MoSi APSM mask using an MSM-100 AIMS tool operating at 248nm as a printability prediction tool. Printability analysis will be used to address differences in intensity, image capture wavelength, defocus, defect size, type, and placement on two substrate materials. Defect correlation to photomask CD error, aerial image intensity error, and MEEF on high-end KrF photomasks will also be studied.

Inspecting alternating phase shift masks by matching stepper conditions

The paper presents a new technology to inspect alternating phase shifting masks. Instead of finding defects based on a size-dependent defect specification, defects are found according to their impact at the wafer CD result. The inspection methodology used is aerial imaging. Phase effects are taking into account inherently. The main advantage of this method is that only defects, which actually affect the wafer result, will be detected and classified. The paper presents first inspection results on alternating phase shifting test masks designed for the 70nm generation.

Inspection of EAPSMs for 193-nm technology generation using a UV-based 365-nm reticle inspection tool

The paper presents the inspection of embedded attenuated phase shift masks for the 193nm lithography generation using UV-based mask inspection systems. Production issues like light calibration due to the existence of different transmissions on the mask and halftone-specific inspection sensitivity settings are discussed. A mask inspection example is presented and the most severe defect types are analyzed. In addition, the mask is investigated using the Linewidth Bias Monitor (LBM) option of the inspection system used, which provides a critical dimension (CD) uniformity map of the entire mask.

Aerial-image based inspection of AAPSM for 193-nm lithography generation

The inspection of alternating phase shifting masks is still one of the major challenges in state-of-the-art mask making. Main issue is that phase defects cannot easily be identified by inspection systems using an inspection wavelength different form the target exposure wavelength. The paper presents inspection results using the Aera193, an aerial image based mask inspection system.

Inspection of aggressive OPC using aerial image-based mask inspection

Inspection of aggressive OPC represents one of the major challenges for todays mask inspection methodologies. Systems are phased with high-density layouts, containing OPC features far below the resolution limit of conventional inspection systems. This causes large amounts of false and nuisance defects, especially on production applications. The paper presents the use of Aera193, a new inspection system using aerial imaging as inspection methodology.

CD uniformity control using aerial image-based mask inspection

The industry roadmap for IC manufacturing at design rules of 90nm and below foresees low k1-factor optical lithography at 193nm exposure wavelength. The mask error enhancement factor (MEEF) describes the phenomenon in which errors in the mask critical dimensions (CDs) are not transferred to the wafer in direct proportion to the optical reduction value of the lithography system. In the low-k1 area, the MEEF becomes a significant problem, as it consumes a larger than anticipated percentage of the CD tolerance budget. As a result mask CD uniformity requirements have been tightened significantly to find MEEF-related CD defects prior to the first printing at the wafer fab. The challenge for todays mask inspection methodology lays in the way defects are detected. Conventional mask inspection detects defects according to their dimensions on the mask. Finding MEEF-related CD defects is a challenge as these defects are often caused by CD deviations close to metrology resolution. The paper investigates CD uniformity control using aerial image based mask inspection. The fundamental difference to todays inspection methodology is that a defect is detected based on its impact onto the aerial image projected by the given mask. In order to emulate the aerial image, lithography condition like Numerical Aperture and illumination need to be known to the inspection system. As a large portion of the MEEF is based on the lithography exposure system, MEEF defects can be detected.

Aerial-image-based off-focus inspection: lithography process window analysis during mask inspection

The industry roadmap for IC manufacturing at design rules of 90nm and below foresees low k1-factor optical lithography at 193nm exposure wavelength. Aggressive model-based OPC are being used more and more frequently in order to achieve the extremely tight mask CD specifications required by 90nm technology node. State-of-the-art mask inspection is challenged to detect CD defects close to metrology resolution. Inspection of OPC is critical; OPC feature dimensions are usually near or below the resolution limits of mask exposure. In addition, chrome defects can be semitransparent and change the intensity of light on the wafer. In this paper aerial-image based mask inspection is investigated and presented. The concept inspects a given mask based on its aerial image with selected wafer exposure conditions, thus “finds only defect which will print”. This paradigm shift in mask inspection philosophy provides the unique opportunities of verifying and controlling the entire aerial image generated by the inspected mask. As reticle enhancement techniques like OPC are designed to enhance the aerial image of a mask, this concept offers a comprehensive way of inspecting these techniques. The inspection is shifted from detecting every single minor change on mask to detecting what on mask could possibly impact the printing image quality on the wafer. In this paper an advanced application of aerial-image based mask inspection is discussed in more detail. As a standard, the Aera193 uses the best-focus aerial image for defect detection. From HNA mask inspection it is a well-known fact, that shifting the inspection off-focus, can provide a more sensitive detection. In the csase of aerial-image based inspection, going off-focus can be compared with lithography exposure out of focus. In other words, the lithography process window will be taken into account for defect detection. This methodology provides additional important information ·Understand process window printability of defects detected at best-focus ·Detect additional defects, which may print at the borders of the process window. This information is of extreme value for wafer lithography and may help by decisions about lithography process and mask usage. Focus of the paper is to analyze the application of aerial image-based off-focus inspection. Advanced OPC test plates are used to analyze detection at best and off-focus. The inspection results are compared to actual wafer results. Wafer lithography benefit is discussed.

Process of manufacturing and inspection of high-end (ternary) tritone EAPSM reticles for 0.13-μm design rule generation

Embedded attenuated phase shift masks (EAPSMs) are being used in the semiconductor industry for high-density patterning of critical layers, such as gate and contact layers of circuit devices, of the 130 nm node and beyond. This paper focuses on the manufacturing and inspection of ternary (tritone) phase shift masks designed for the 130 nm design-rule generation. The manufacturing flow is presented and the use of the ARISTM100i mask inspection system for inspection is demonstrated.