References Cited:
[1] Xiong, X. , Makaram, P. , Busnaina, A., Bakhtari, K., Somu, S., McGruer, N., and Park, J., "Large Scale
Directed Assembly of Nanoparticles Using Nanotrench Templates," Appl. Phys. Lett. 89, 193108 (Nov. 6,
2006).
[2] C.G. Parazzoli, R.B. Greegor, K. Li, B.E.C. Koltenbah, M. Tanielian, Phys. Rev. Lett. 90, 107401, 2003.
[3] P. V. Parimi, W. T. Lu, P. Vodo, J. Sokoloff, and S. Sridhar, Phys. Rev. Lett. 92, 127401, 2004.
[4] R. A. Shelby, D. R. Smith and S. Schultz, Science 292, 77, 2001.
[5] P. Vodo, P. V. Parimi, W. T. Lu, S. Sridhar and R. Wing, Appl. Phys. Lett. 85, 1858 (2004).
[6] E. Di Gennaro, P. V. Parimi, W. T. Lu, and S. Sridhar, Phys. Rev. B, in print, July 2005.
[7 M. Notomi, Optical and Quantum Elec. 34, 133 (2002).
[8] P. V. Parimi, W. T. Lu, P. Vodo, and S. Sridhar, Nature 426, 404 (2003).
[9] Y. Akahori; T. Ohyama; T. Yamada; K. Katoh; T. Ito, “High-speed photoreceivers using solder bumps and
microstrip lines formed on a silicon optical bench”, IEEE Photonics Technology Letters, vol. 11, no.4, pp.
454-56, August 1999.
[10] S. H. Hwang; J. Y. An; M.-H. Kim; W. C. Choi; S. R.l Cho; S. H. Lee; H. S. Cho; H.- H. Park, “VCSEL
array module using (111) facet mirrors of a V-grooved silicon optical bench and angled fibers”, IEEE
Photonics Technology Letters, vol. 17, no.2, pp. 477-79, Feb 2005.
[11] M. H. Choi, H. J. Koh; E. S. Yoon, K. C. Shin, K. C. Song; “Self-aligning silicon groove technology
platform for the low cost optical module”, 49th Electronic Components and Technology Conference, pp.
1140-44, June 1999.
[12] M.S. Dresselhaus, G. Dresselhaus, P. Avouris, Carbon nanotubes: synthesis, structure, properties, and
applications 2001 Springer, Berlin, New York.
[13] P.M. Ajayan, “Nanotubes from carbon”, Chemical Reviews 99, 1787-1799, 1999
[14] B.Q. Wei, R. Vajtai, Y.J. Jung, P.M. Ajayan et al., Nature 416, 495, 2002
[15] Y.J. Jung , Y. Homma, T. Ogino, P.M. Ajayan et al., J. Phys. Chem. B 107,6859, 2003
[16] B.Q. Wei, R. Vajtai, Y.J. Jung, P.M. Ajayan et al. Nature 416, 495, 2002
[17] Radner W, Zehetmayer M, Aufreiter R, Mallinger R. Interlacing and cross-angle distribution of collagen
lamellae in the human cornea. Cornea. 1998; 17; 537-43.
[18] Birk DE, Trelstad RL. Fibroblasts create compartments in the extracellular space where collagen polymerizes
into fibrils and fibrils associate into bundles. Annals of the New York Academy of Sciences. 1985; 460; 25866.
[19] Hay ED. Cell Biology of the Extracellular Matrix. 2nd ed, ed.Hay ED. 1991, New York: Plenum Press. 468.
[20] Germain L, Auger FA, Grandbois E, et al. Reconstructed human cornea produced in vitro by tissue
engineering. Pathobiology. 1999; 67; 140-7.
[21] Germain L, Carrier P, Auger FA, Salesse C, Guerin SL. Can we produce a human corneal equivalent by
tissue engineering? Prog Retin Eye Res. 2000; 19; 497-527.
[22] Griffith M, Osborne R, Munger R, et al. Functional human corneal equivalents constructed from cell lines.
Science. 1999; 286; 2169-72.
[23] Kadler KE, Hojima Y, Prockop DJ. Assembly of collagen fibrils de novo by cleavage of the type I pCcollagen with procollagen C-proteinase. Assay of critical concentration demonstrates that collagen selfassembly is a classical example of an entropy-driven process. J Biol Chem. 1987; 262; 15696-701.
[24] Kadler KE, Hojima Y, Prockop DJ. Assembly of type I collagen fibrils de novo. Between 37 and 41 degrees
C the process is limited by micro-unfolding of monomers. J Biol Chem. 1988; 263; 10517-23.
[25] Kadler KE, Holmes DF, Trotter JA, Chapman JA. Collagen fibril formation. Biochemical Journal. 1996;
316; 1-11.
[26] Birk DE, Fitch JM, Babiarz JP, Doane KJ, Linsenmayer TF. Collagen fibrillogenesis in vitro: interaction of
types I and V collagen regulates fibril diameter. J Cell Sci. 1990; 95 (Pt 4); 649-57.
[27] Brown CT, Lin P, Walsh MT, Gantz D, Nugent MA, Trinkaus-Randall V. Extraction and purification of
decorin from corneal stroma retain structure and biological activity. Protein Expr Purif. 2002; 25; 389-99.
[28] Chakravarti S, Magnuson T, Lass JH, Jepsen KJ, LaMantia C, Carroll H. Lumican regulates collagen fibril
assembly: skin fragility and corneal opacity in the absence of lumican. J Cell Biol. 1998; 141; 1277-86.
[29] Chakravarti S, Petroll WM, Hassell JR, et al. Corneal opacity in lumican-null mice: defects in collagen fibril
structure and packing in the posterior stroma. Invest Ophthalmol Vis Sci. 2000; 41; 3365-73.
[30] Guido S, Tranquillo RT. Methodology for the systematic and quantitative study of cell contact guidance in
oriented collagen gels. Journal of Cell Science. 1993; 105; 317-331.
[31] Birk DE. Type V collagen: heterotypic type I/V collagen interactions in the regulation of fibril assembly.
Micron. 2001; 32; 223-37.
[32] Kypreos KE, Birk D, Trinkaus-Randall V, Hartmann DJ, Sonenshein GE. Type V collagen regulates the
assembly of collagen fibrils in cultures of bovine vascular smooth muscle cells. J Cell Biochem. 2000; 80;
146-55.
[33] Wenstrup RJ, Florer JB, Brunskill EW, Bell SM, Chervoneva I, Birk DE. Type v collagen controls the
initiation of collagen fibril assembly. J Biol Chem. 2004; 279; 53331-7.
[34] Hella-C Scheer, Schulz, H., Hoffmann, T. and Torres, C. M. S. in Handbook of Thin Film Materials. H. S.
Nalwa, Ed.; Academic Press, San Diego, 2001, p 1-61.
[35] Chou, S. Y., Krauss, P. R. and Renstrom, P. J., 1995. Imprint of sub-25 nm vias and trenches in polymers.
Applied Physics Letters, 67, 3114-3116.
[36] Becker, H. and Heim, U. IEEE International Conference on Microelectromechanical Systems, Orlando, 1999,
pp 228-231.
[37] Becker, H. and Locascio, L. E., 2002. Polymer microfluidic devices. Talanta, 56, 267-287.
[38] http://www.deluxemedia.com/images/replication.pdf, last accessed November 30, 2005.
[39] Ltd., D. G. M. S. 2005.
[40] Fay, B., 2002. Advanced optical lithography development, from UV to EUV Microelectronic Engineering,
61-62, 11-24.
[41] Lehmann, F., Richter, G., Borzenko, T., Hock, V., Schmidt, G. and Molenkamp, L. W., 2003. Fabrication of
sub-10-nm Au-Pd structures using 30 keV electron beam lithography and lift-off. Microelectronic
Engineering, 65, 327-333.
[42] Yoon, S.-h., Srirojpinyo, C., Lee, J., Sung, C., Mead, J. L. and Barry, C. M. F. ANTEC 2004, Chicago, 2004,
pp 738-742.
[43] Yoon, S.-h., Srirojpinyo, C., Lee, J. S., Mead, J. L., Matsui, S. and Barry, C. M. F. SPIE International
Symposia, Smart Structures & Materials/NDE, San Diego, March 7 – 9, 2005 2005, pp 107-116.
[44] Malloy, R. A. Plastics Part Design for Injection Molding. Hanser Gardner Publications, Cincinnati, OH, 1994.
[45] R Dussart, M. Boufnichel, G. Marcos, P. Lefaucheux, A Basillais1, R Benoit3, T Tillocher1, X Mellhaoui1,
H. Estrade-Szwarckopf, and P. Ranson. “Passivation mechanisms in cryogenic SF6/O2 etching process,” J.
Micromech. Microeng. 14 (2004) 190–196.
[46] S. Aachboun, P. Ranson, C. Hilbert, and M. Boufnichel, “Cryogenic etching of deep narrow trenches in
silicon,” Journal of Vacuum Science & Technology A, Volume 18, Issue 4, pp. 1848-1852.
[47] Deirdre L. Olynick, Erik H. Anderson, Bruce Harteneck, and Eugene Veklerov, “Substrate cooling efficiency
during cryogenic inductively coupled plasma polymer etching for diffractive optics on membranes,” Journal
of Vacuum Science & Technology B:, Volume 19, Issue 6, pp. 2896-2900.
[48] R. Hsiao, K. Yu, L. S. Fan, T. Pandhumsopom, H. Sanitini, S. A. Macdonald, and N. Robertson,
“Anisotropic Etching of a Novalak-Based Polymer at Cryogenic Temperature,” J. Electrochem. Soc.,
Volume 144, Issue 3, pp. 1008-1013 (March 1997).