In Proceedings of the SPIE: August 14–16 2006 Volume 6317 Edited

In Proceedings of the SPIE: August 14–16 2006 Volume 6317. Edited by: Khounsay AM, Morawe C, Goto S. San Diego, California, USA; 2006:6317B-1. 8. Higashi Y, Takaie Y, Endo K, Kume T, Enami K, Yamauchi K, Yamamura K, Sano Y, Ueno K, Mori Y: A new designed ultra-high precision profiler. In Proceedings of the SPIE: August 30. Edited by: Assoufid L, Takacs P, Ohtsuka M. Bellingham, San Diego; 2007:6704D-1. Volume

9. Matsumura H, Tonaru D, Kitayama T, Usuki K, Kojima T, Uchikoshi J, Higashi Y, Endo K: Effects of a laser beam profile to measure an aspheric mirror on a high-speed nanoprofiler using normal vector tracing method. Curr Appl Phys 2012, 12:S47–51.CrossRef 10. Watanabe T, Fujimoto H, Masuda T: Self-calibratable rotary encoder. J Phys: Conf Series 2005, 13:240–245.CrossRef 11. Takao K, Daisuke T, Hiroki M, Junichi U, Yasuo H, Katsuyosi E: Development of a high-speed nanoprofiler using normal vector

tracing. In Proceedings of SPIE 2012 Volume 561. Edited by: Lee WB, Cheung CF, To S. Bellingham: SPIE; 2012:606–611. Competing interests The authors declare that they have no competing interests. Authors’ contributions KU carried out the Ipatasertib order measurements of the figure of the selleck kinase inhibitor concave spherical mirror and the flat mirror, and drafted the manuscript. TK (Kitayama) developed an algorithm for reproduction of the figure

from the normal vectors and the coordinates. HM designed the optical head. TK (Kojima) developed the data in the acquisition system. JU adjusted the system of the high-speed nanoprofiler. YH attached the concave spherical mirror and the flat mirror to the high-speed nanoprofiler and aligned them. KE conceived of the study and participated in its design and coordination. All authors read and approved the final manuscript.”
“Background Cyclic nucleotide phosphodiesterase Laser technologies can be successfully utilized for the production of carbon-nanostructured materials exhibiting fascinating structural and physical properties such as carbon nanotubes [1], carbon nanohorns [2], carbon nanofoams [3], or shell-shaped carbon nanoparticles [4]. Our group discovered the production of metal-nanostructured foams (NCFs) by laser ablation of triphenylphosphine (PPh3)-containing organometallic targets [5]. We then demonstrated that organic ligands can act as efficient carbon sources for the laser ablation production of carbon nanomaterials. Metal-NCFs are three-component materials which consist of amorphous carbon aggregates, metal nanoparticles embedded in amorphous carbon matrices, and graphitic nanostructures. The metal-NCF composition, metal nanoparticle size, and dilution (i.e.

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