Robert L. Dean scite author profile

Photomask complexity threatens to outpace mask pattern generator productivity, as semiconductor devices are scaled down and optical proximity correction (OPC) becomes commonplace. Raster scan architectures are well suited to the challenge of maintaining mask throughput and mask quality despite these trends. The MEBES ® eXaraä mask pattern generator combines the resolution of a finely focused 50 keV electron beam with the productivity and accuracy of Raster Graybeamä writing. Features below 100 nm can be imaged, and OPC designs are produced with consistent fidelity. Write time is independent of resist sensitivity, allowing high-dose processes to be extended, and relaxing sensitivity constraints on chemically amplified resists. Data handling capability is enhanced by a new hierarchical front end and hiearchical data format, building on an underlying writing strategy that is efficient for OPC patterns. A large operating range enables the MEBES eXara system to support the production of 100 nm photomasks, and the development of 70 nm masks.

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Electron Beam Proximity Effect Correction on the MEBES eXara Mask Pattern Generator

Dean

Baik

2002

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100-nm OPC mask patterning using raster-scan 50-kV pattern generation technology

Abboud¹,

Baik²,

Chakarian³

et al. 2002

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The complexity of photomasks is rapidly increasing as semiconductor devices are scaled down and optical proximity correction (OPC) becomes commonplace. Raster scan architectures are well suited to the challenge of maintaining mask throughput despite these trends. Electron-beam techniques have the resolution to support OPC requirements into the foreseeable future. The MEBES ® eXara mask pattern generator combines the resolution of a finely focused electron probe with the productivity and accuracy of Raster Graybeam patterning. Features below 100nm can be created, and OPC designs are produced with consistent fidelity. Write time is independent of resist sensitivity, allowing high-dose processes to be extended, and relaxing sensitivity constraints on advanced chemically amplified resists. The system is designed for the production of 100nm photomasks, and will support the development of 70nm masks.

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Robert L. Dean

REAP (raster e-beam advanced process) using 50-kV raster e-beam system for sub-100-nm node mask technology

Lithographic analysis of multipass gray writing strategy for electron-beam pattern generation

Raster scan patterning solution for 100- and 70-nm OPC masks

Electron Beam Proximity Effect Correction on the MEBES eXara Mask Pattern Generator

100-nm OPC mask patterning using raster-scan 50-kV pattern generation technology

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