Frank Cropanese scite author profile

Frank Cropanese

5Publications

53Citation Statements Received

13Citation Statements Given

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Affiliations

Rochester Institute of Technology

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Mask-induced polarization

Estroff

Fan

Bourov³

et al. 2004

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The objective of this paper is to study the polarization induced by mask structures. Rigorous coupled-wave analysis (RCWA) was used to study the interaction of electromagnetic waves with mask features. RCWA allows the dependence of polarization effects of various wavelengths of radiation on grating pitch, profile, material, and thickness to be studied. The results show that for the five different mask materials examined, the material properties, mask pitch, and illumination all have a large influence on how the photomask polarizes radiation.

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Water immersion optical lithography for 45-nm node

Smith

Kang

Bourov³

et al. 2003

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It is possible to extend optical lithography by using immersion imaging methods. Historically, the application of immersion optics to microlithography has not been seriously pursued because of the alternative solutions available. As the challenges of shorter wavelength become increasingly difficult, immersion imaging becomes more feasible. We present results from research into 193nm excimer laser immersion lithography at extreme propagation angles (such as those produces with strong OAI and PSM). This is being carried out in a fluid that is most compatible in a manufacturable process, namely water. By designing a system around the optical properties of water, we are able to image with wavelengths down to 193nm. Measured absorption is below 0.50 cm -1 at 185nm and below 0.05 cm -1 at 193nm. Furthermore, through the development of oblique angle imaging, numerical apertures approaching 1.0 in air and 1.44 in water are feasible. The refractive index of water at 193nm (1.44) allows for exploration of the following:1. k 1 values approaching 0.17 and optical lithography approaching 35nm. 2. Polarization effects at oblique angles (extreme NA). 3. Immersion and photoresist interactions with polarization. 4. Immersion fluid composition, temperature, flow, and micro-bubble influence on optical properties (index, absorption, aberration, birefringence). 5. Mechanical requirements for imaging, scanning, and wafer transport in a water media. 6. Synthesizing conventional projection imaging via interferometric imaging.

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Immersion microlithography at 193 nm with a Talbot prism interferometer

Bourov¹,

Fan

Cropanese

et al. 2004

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A Talbot interference immersion lithography system that uses a compact prism is presented. The use of a compact prism allows the formation of a fluid layer between the optics and the image plane, enhancing the resolution. The reduced dimensions of the system alleviate coherence requirements placed on the source, allowing the use of a compact ArF excimer laser. Photoresist patterns with a half-pitch of 45 nm were formed at an effective NA of 1.05. In addition, a variable-NA immersion interference system was used to achieve an effective NA of 1.25. The smallest half-pitch of the photoresist pattern produced with this system was 38 nm.

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Hyper NA water immersion lithography at 193nm and 248nm

Smith

Fan

Zhou

et al. 2004

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Extending optics to 50 nm and beyond with immersion lithography Immersion lithography can allow for theoretical imaging to /4n (where n is the refractive index of imaging fluid). As 193 nm and 248 nm technology is pushed toward this limit, experimental data becomes increasingly important. This paper describes research carried out to explore the limitations of water immersion lithography and its extension to higher numerical aperture values using modifications to the imaging fluid. Resist imaging to 38 nm is demonstrated using water as an imaging fluid. Several alternative fluids are presented including phosphates, sulfates, and halides, which are shown to increase the refractive index of water.

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Water immersion optical lithography at 193 nm

Smith

Bourov

Kang

et al. 2004

J. Micro/Nanolith. MEMS MOEMS

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Frank Cropanese

Mask-induced polarization

Water immersion optical lithography for 45-nm node

Immersion microlithography at 193 nm with a Talbot prism interferometer

Hyper NA water immersion lithography at 193nm and 248nm

Water immersion optical lithography at 193 nm

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