Nicholas A. Stacey
University of Texas at Austin
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Featured researches published by Nicholas A. Stacey.
Journal of Vacuum Science & Technology B | 2003
Douglas J. Resnick; William J. Dauksher; David P. Mancini; Kevin J. Nordquist; Todd C. Bailey; Stephen C. Johnson; Nicholas A. Stacey; John G. Ekerdt; C. G. Willson; S. V. Sreenivasan; N. Schumaker
The escalating cost for next generation lithography (NGL) tools is driven in part by the need for complex sources and optics. The cost for a single NGL tool could exceed
Journal of Vacuum Science & Technology B | 2004
Eui Kyoon Kim; Nicholas A. Stacey; Britain J. Smith; Michael D. Dickey; Stephen C. Johnson; Brian C. Trinque; C. G. Willson
50M in the next few years, a prohibitive number for many companies. As a result, several researchers are looking at low cost alternative methods for printing sub-100 nm features. In the mid-1990’s, several research groups started investigating different methods for imprinting small features. Many of these methods, although very effective at printing small features across an entire wafer, are limited in their ability to do precise overlay. In 1999, Colburn et al. [Proc. SPIE 379 (1999)] discovered that imprinting could be done at low pressures and at room temperatures by using low viscosity UV curable monomers. The technology is typically referred to as step and flash imprint lithography. The use of a quartz template enabled the photocuring process to occur and also opened up the potential for optical alignment of the wafer and template. ...
Emerging Lithographic Technologies VII | 2003
Stephen C. Johnson; Todd C. Bailey; Michael D. Dickey; Britain J. Smith; Eunha K. Kim; Andrew Thomas Jamieson; Nicholas A. Stacey; John G. Ekerdt; C. Grant Willson; David P. Mancini; William J. Dauksher; Kevin J. Nordquist; Douglas J. Resnick
Until now, acrylates have been the monomers of choice for use for step and flash imprint lithography (SFIL) etch barrier formulations, in part because of the commercial availability of silicon-containing acrylates (necessary for etch resistance), together with their low viscosities and capability for rapid photopolymerization. However, despite many desirable properties, the polymerization of acrylates via radical chain propagation causes some potential issues in the SFIL process as a result of the inhibition of these processes by oxygen. Vinyl ethers are prime candidates to replace acrylates. Their curing proceeds by a cationic mechanism, which is insensitive to oxygen and very rapid, while the vinyl ether group contribution to viscosity is significantly lower than that of an acrylate, silicon-containing vinyl ethers are not widely commercially available, and so were synthesized for this study. As expected, formulations based on these vinyl ethers were lower viscosity and faster curing than the acrylate e...
Emerging Lithographic Technologies VIII | 2004
Frank Y. Xu; Nicholas A. Stacey; Michael P. C. Watts; Van N. Truskett; Ian M. Mcmackin; Jin Choi; Philip Schumaker; Ecron Thompson; Daniel A. Babbs; S. V. Sreenivasan; C. Grant Willson; Norman E. Schumaker
Recent work on Step and Flash Imprint Lithography (SFIL) has been focused on process and materials fundamentals and demonstration of resolution capability. Etch transfer rpocesses have been developed that are capable of transferring imprinted images though 150 nm of residual etch barrier, yielding sub 50 nm lines with aspect ratios greater than 8:1. A model has been developed for the photoinitiated, free radical curing of the acrylate etch barrier materials that have been used in the SFIL process. This model includes the effects of oxygen transport on the kinetics of the reaction and yields a deeper understanding of the importance of oxygen inhibition, and the resulting impact of that process on throughput and defect generation. This understanding has motivated investigation of etch barrier materials such as vinyl ethers that are cured by a cationic mechanism, which does not exhibit these same effects. Initial work on statistical defect analysis has is reported and it does not reveal pathological trends.
Emerging Lithographic Technologies VIII | 2004
Ryan L. Burns; Stephen C. Johnson; Gerard M. Schmid; Eui K. Kim; Michael D. Dickey; Jason E. Meiring; Sean D. Burns; Nicholas A. Stacey; C. Grant Willson; Diana Convey; Yi Wei; Peter Fejes; Kathleen A. Gehoski; David P. Mancini; Kevin J. Nordquist; William J. Dauksher; Douglas J. Resnick
The Step and Flash Imprint Lithography (S-FILTM) process is a step and repeat nano-replication technique based on UV curable low viscosity liquids. Molecular Imprints, Inc. (MII) develops commercial tools that practice the S-FIL process. This talk will present the imprint materials that have been developed to specifically address the issue of process life and defects. The S-FIL process involves field-to-field dispensing of low viscosity (<5 cps) UV cross-linkable monomer mixtures. The low viscosity liquid leads to important advantages that include: • Insensitivity to pattern density variations • Improved template life due to a lubricated template-wafer interface avoids “hard contact” between template and wafer • Possibility for lubricated (in-situ) high-resolution alignment corrections prior to UV exposure The materials that are optimal for use in the S-FIL process need to possess optimal wetting characteristics, low evaporation, no phase separation, excellent polymer mechanical properties to avoid cohesive failure in the cured material, low adhesion to the template, and high adhesion to the underlying substrate. Over 300 formulations of acrylate based monomer mixtures were developed and studied. The imprint materials were deemed satisfactory based on the process of surviving imprinting more than 1500 imprints without the imprints developing systematic or repeating defects. For the purpose of these process studies, printing of sub-100 nm pillars and contacts is used since they represent the two extreme cases of patterning challenge: pillars are most likely to lead to cohesive failure in the material; and contacts are most likely to lead to mechanical failure of the template structures.
Emerging Lithographic Technologies VII | 2003
Douglas J. Resnick; William J. Dauksher; David P. Mancini; Kevin J. Nordquist; Todd C. Bailey; Stephen C. Johnson; Nicholas A. Stacey; John G. Ekerdt; C. Grant Willson; S. V. Sreenivasan; Norman E. Schumaker
Step and Flash Imprint Lithography (SFIL) is a revolutionary next generation lithography option that has become increasingly attractive in recent years. Elimination of the costly optics of current step and scan imaging tools makes SFIL a serious candidate for large-scale commercial patterning of critical dimensions below ~50 nm. This work focuses on the kinetics of the UV curing of the liquid etch barrier and the resulting densification/contraction of the etch barrier as it solidifies during this step. Previous experimental work in our group has measured the bulk densification of several etch barrier formulations, typically about 9 % (v/v). It remains unknown, however, how much etch barrier contraction occurs during the formation of nano-scale features. Furthermore, it is of interest to examine how changes in monomer pendant group size impact imprinted feature profiles. This work provides answers to these questions through a combination of modeling and experimental efforts. Densification due to the photopolymerization reaction and the resulting shift from Van der Waals’ to covalent interactions is modeled using Monte-Carlo techniques. The model allows for determination of extent of reaction, degree of polymerization, and local density changes as a function of the etch barrier formulation and the interaction energies between molecules (including the quartz template). Experimental efforts focus on a new technique to examine trench profiles in the quartz template using TEM characterization. Additionally, SEM images of imprinted images from various etch barrier formulations were examined to determine local contraction of the etch barrier. Over a large range of etch barrier formulations, which range from 10 - 20 % volumetric contraction as bulk materials, it was found that dense 100 nm lines printed approximately the same size and shape.
Proceedings of SPIE - The International Society for Optical Engineering | 2003
Britain J. Smith; Nicholas A. Stacey; Joseph P. Donnelly; David Onsongo; Todd C. Bailey; Christopher J. Mackay; Douglas J. Resnick; William J. Dauksher; David P. Mancini; Kevin J. Nordquist; S. V. Sreenivasan; Sanjay K. Banerjee; John G. Ekerdt; Grant Willson
The escalating cost for Next Generation Lithography (NGL) tools is driven in part by the need for complex sources and optics. The cost for a single NGL tool could exceed
Archive | 2004
Byung Jin Choi; Frank Y. Xu; Nicholas A. Stacey; Van Xuan Hong Truskett; Michael P. C. Watts
50M in the next few years, a prohibitive number for many companies. As a result, several researchers are looking at low cost alternative methods for printing sub-100 nm features. In the mid-1990s, several resarech groups started investigating different methods for imprinting small features. Many of these methods, although very effective at printing small features across an entire wafer, are limited in their ability to do precise overlay. In 1999, Willson and Sreenivasan discovered that imprinting could be done at low pressures and at room temperatures by using low viscosity UV curable monomers. The technology is typically referred to as Step and Flash Imprint Lithography. The use of a quartz template enabled the photocuring process to occur and also opened up the potential for optical alignment of teh wafer and template. This paper traces the development of nanoimprint lithography and addresses the issues that must be solved if this type of technology is to be applied to high-density silicon integrated circuitry.
Archive | 2004
Frank Y. Xu; Michael P. C. Watts; Nicholas A. Stacey
Step and Flash Imprint Lithography (SFIL) is an alternative lithography technique that enables patterning of sub-100 nm features at a cost that has the potential to be substantially lower than either conventional projection lithography or proposed next generation lithography techniques. SFIL is a molding process that transfers the topography of a rigid transparent template using a low-viscosity, UV-curable organosilicon solution at room temperature and with minimal applied pressure. Employing SFIL technology we have successfully patterned areas of high and low density, semi-dense and isolated lines down to 20 nm, and demonstrated the capability of layer-to-layer alignment. We have also confirmed the use of SFIL to produce functional optical devices including a micropolarizer array consisting of orthogonal 100 nm titanium lines and spaces fabricated using a metal lift-off process. This paper presents a demonstration of the SFIL technique for the patterning of the gate level in a functional MOSFET device.
Archive | 2005
Michael N. Miller; Edward B. Fletcher; Nicholas A. Stacey; Michael P. C. Watts; Ian M. Mcmackin