Journal Papers

    1. S. Maruo, O. Nakamura and S. Kawata, “Three-dimensional microfabrication with two-photon absorbed photopolymerization,” Optics Letters 22, no.2, 132-134 (1997).  Number of citations1539@Google Scholar(2018.4)
    2. S. Maruo, O. Nakamura and S. Kawata, “Evanescent-wave holography by use of surface-plasmon resonance,” Applied Optics 36, no. 11, 2343-2346 (1997).
    3. S. Maruo and S. Kawata, “Two-Photon-Absorbed Near-Infrared Photopolymerization for Three-Dimensional Microfabrication,” Journal of Microelectromechanical Systems 7, no. 4, 411-415 (1998). Number of citations274@Google Scholar(2018.4)
    4. S. Maruo and K. Ikuta, “Three-dimensional microfabrication by use of single-photon-absorbed polymerization”, Applied Physics Letters 76,no. 19, 2656-2658 (2000). Number of citations142@Google Scholar(2018.4)

    1. S. Maruo and K. Ikuta, “Submicron stereolithography for the production of freely movable mechanisms by using single-photon polymerization,”Sensors and Actuators A 100, no. 1, 70-76 (2002). Number of citations167@Google Scholar(2018.4)
    2. S. Maruo, K. Ikuta and H. Korogi,“Submicron manipulation tools driven by light in a liquid,” Applied Physics Letters 82,no. 1, 133-135 (2003). Number of citations213@Google Scholar(2018.4)
    3. S. Maruo, K. Ikuta and H. Korogi,“Force-controllable, optically driven micromachines fabricated by single-step two-photon microstereolithography,” Journal of Microelectromechanical Systems 12, no. 5, 533-539 (2003).
    4. S. Maruo and H. Inoue, “Optically driven micropump produced by three-dimensional two-photon microfabrication,” Appl. Phys. Lett. 89, no. 14, Art No. 144101 (2006). Number of citations206@Google Scholar(2018.4)
    5. K. Mukai, T. Yoshimura, S. Kitayama, S. Maruo, “Electroless and electrolytic plating of photopolymerized resin for use in the micro-molding of three-dimensional nickel structures,” Journal of photopolymer science and technology 20, no. 2, 285-290 (2007).
    6. K. Mukai, T. Yoshimura, S. Maruo, “Micromolding of three-dimensional metal structures by electroless plating of photopolymerized resin,” Jpn. J. of Appl. Phys. 46 (4B), 2761-2763 (2007).
    7. S. Maruo and H. Inoue, “Optically driven viscous micropump using a rotating microdisk,” Appl. Phys. Lett. 91, no. 8, Art No. 084101 (2007).
    8. S. Maruo and Y. Hiratsuka, “Optically driven micromanipulators with rotating arms,” Journal of Robotics and Mechatronics,19, no. 5, 565-568 (2007).
    9. S. Maruo and T. Saeki, “Femtosecond laser direct writing of metallic microstructures by photoreduction of silver nitrate in a polymer matrix,” Optics Express 16, Issue 2, 1174-1179 (2008).
    10. K. Mukai, S. Kitayama, S. Maruo, “Electroless and electrolytic plating of Ni, Cu, and CoxFe2-xO4 for the application of three-dimensional micro-molding,” Journal of photopolymer science and technology 21, no. 1, 53-58 (2008).
    11. K. Mukai, S. Kitayama, T. Yoshimura and S. Maruo, “Ferrite and copper electroless plating of photopolymerized resin for micromolding of three-dimensional structures,” Jpn. J. of Appl. Phys. 47, no. 4, 3232-3235 (2008).
    12. S. Saito, Y. Katoh, H. Kokubo, M. Watanabe, and S. Maruo,”Development of a soft actuator using a photocurable ionic gel,” J. Micromech. Microeng. 19, 035005 (2009).
    13. S. Maruo, T. Hasegawa and N. Yoshimura “Replication of Three-Dimensional Rotary Micromechanism by Membrane-Assisted Transfer Molding,” Jpn. J. Appl. Phys. 48, no. 6, 06FH05 (2009).
    14. M. Inada, D. Hiratsuka, J. Tatami and S. Maruo, “Fabrication of Three-Dimensional Transparent SiO2 Microstructures by Microstereolithographic Molding,” Jpn. J. Appl. Phys. 48, no. 6, 06FK01 (2009).
    15. S. Maruo, A. Takaura, and Y. Saito, “Optically driven micropump with a twin spiral microrotor,” Optics Express 17, Iss. 21, 18525–18532 (2009).
    16. S. Maruo, T. Hasegawa, and N. Yoshimura, “Single-anchor support and supercritical CO2 drying enable high-precision microfabrication of three-dimensional structures,” Optics Express 17, Iss. 23, 20945–20951 (2009).
    17. K. Mukai, S. Kitayama, Y. Kawajiri, and S. Maruo, “Micromolding for three-dimensional metal microstructures using stereolithography of photopolymerized resin,” Microelectronic Engineering 86, 1169-1172 (2009).
    18. S. Murakami, M. Ikegame, K. Okamori, and S. Maruo, “Evanescent-Wave-Driven Microrotors Produced by Two-Photon Microfabrication,” Jpn. J. Appl. Phys. 50, 06GM16 (2011).
    19. T. Torii, M. Inada, and S. Maruo, “Three-Dimensional Molding based on Microstereolithography Using Beta-Tricalcium Phosphate Slurry for the Production of Bioceramic Scaffolds,” Jpn. J. Appl. Phys. 50, no. 6, 06GL15 (2011).
    20. T. Ikegami, M. P. Stocker, K. Monaco, J. T. Fourkas, and S. Maruo, “Fabrication of three-dimensional metalized movable microstructures by the combination of two-photon microfabrication and electroless plating,” Jpn. J. Appl. Phys. 51, no. 6, 06FL17 (2012).
    21. T. Ikegami, R. Ozawa, M. P. Stocker, K. Monaco, J. T. Fourkas, and S. Maruo, “Development of optically-driven metallic microrotors using two-photon microfabrication,” Journal of Laser Micro / Nanoengineering, 8, no. 1, 6-10 (2013).
    22. Y. Daicho, T. Murakami, T. Hagiwara, and S. Maruo, “Formation of three-dimensional carbon microstructures via two-photon microfabrication and microtransfer molding,” Opt. Mater. Express, 3, Iss. 6, 875–883 (2013).
    23. K. Monri and S. Maruo, “Three-dimensional ceramic molding based on microstereolithography for the production of piezoelectric energy harvesters,” Sensors and Actuators A 200, 31–36 (2013).
    24. T. Zandrini, S. Taniguchi, S. Maruo, “Magnetically driven micromachines created by two-photon microfabrication and selective electroless magnetite-plating for lab-on-a-chip applications,” Micromachines 8, No. 2, Article No. 35 (pp. 1-8) (2016).
    25. K. Kakegawa, R. Harigane, M. Aida, H. Miyahara, S. Maruo, A. Okino, “Development of a High-Density Microplasma Emission Source for a Micro Total Analysis System,” Analytical Sciences 33, No. 4, 505-510 (2017).
    26. T. Kageyama, C. Yoshimura, D. Myasnikova, K. Kataoka, T. Nittami, S. Maruo, and J. Fukuda, “Spontaneous hair follicle germ (HFG) formation in vitro, enabling the large-scale production of HFGs for regenerative medicine,” Biomaterials 154, 291-300 (2018).

 

Books

    1. S. Maruo (Contributers), Chapter 7(pp.275-314): Manipulation of Microobjects by Optical Tweezers, Microfluidic Technologies for Miniaturized Analysis Systems, MEMS Reference Shelf, Hardt, Steffen; Schonfeld, Friedhelm (Eds.) 2007(Springer).
    2. S. Maruo (Contributers), Chapter 12(pp.291-309): Optically Driven Micromachines for Biochip Application, Nano- and Micromaterials Series: Advances in Materials Research , Vol. 9,Ohno, K.; Tanaka, M.; Takeda, J.; Kawazoe, Y. (Eds.) 2008(Springer).

    1. S. Maruo (Contributers), Chapter 10(pp.307-331): Optically driven microfluidic devices produced by multiphoton microfabrication, Optical Nano and Micro Actuator Technology, George K. Knopf; Yukitoshi Otani (Eds.) 2012 (CRC Press).

    1. S. Taniguchi and S. Maruo (Contributers), Chapter 12.2 “Remotely driven micro machines produced by two-photon microfabrication,” Three-Dimensional Microfabrication Using Two-Photon Polymerization,Fundamentals, Technology, and Applications, T Baldacchini (Ed), 2015.10.2, 293-309 (Springer).http://www.amazon.co.jp/Three-Dimensional-Microfabrication-Using-Two-Photon-Polymerization/dp/0323353215
    2. S. Maruo (Contributers), “Microfluidic devices produced by two-photon induced polymerization,” Multiphoton Lithography: Techniques, Materials, and Applications, Jürgen Stampfl, Robert Liska, Aleksandr Ovsianikov (Ed), 2016.9.12, 315-334 (Wiley). ISBN: 978-3-527-33717-0