Results are presented from study of the effi ciency (ablated mass per unit energy, mechanical recoil momentum per unit energy) of laser ablation for a light-curable polymer. A substantial difference is seen between the thresholds and indicated criteria for laser ablation effi ciency in the liquid and cured phases. The highest energy effi ciency for laser ablation (~22.6 %) is achieved when the initially liquid polymer is exposed to radiation with the wavelength optimal for photopolymerization (365 ± 15 nm).
Similar content being viewed by others
References
A. Ravve, Light-Associated Reactions of Synthetic Polymers, Springer Science, New York (2006).
J. E. Sinko and A. V. Pakhomov, Proc. AIP, 997, 195–208 (2008).
E. Yu. Loktionov, A. V. Ovchinnikov, Yu. Yu. Protasov, Yu. S. Protasov, and D. S. Sitnikov, Zh. Prikl. Spektrosk., 79, No. 1, 114–121 (2012).
E. Yu. Loktionov, A. V. Ovchinnikov, Yu. Yu. Protasov, and D. S. Sitnikov, Zh. Prikl. Spektrosk., 77, No. 4, 604–611 (2010).
B. Wang, L. Li, Z.-P. Tang, and J. Cai, Proc. AIP, 1230, No. 1, 243–253 (2010).
X.-Q. Li, Y.-J. Hong, and G.-Q. He, J. Propuls. Technol., 31, No. 1, 105–110 (2010).
F. N. Lyubchenko, A. V. Fedenev, N. A. Bosak, A. N. Chumakov, A. N. Panchenko, and V. F. Tarasenko, Kosmonavtika Raketostroenie, No. 3, 62–74 (2009).
S. Uchida, Effi cient Laser Ablation. Final Report No. AOARD 044033, Institute for Laser Technology, Osaka (2006).
Z.-Y. Zheng, Z.-J. Fan, S.-W. Wang, A.-G. Dong, J. Xing, and Z.-L. Zhange, Chin. Phys. Lett., 29, No. 9, 095202 (2012).
S. Choi, T.-H. Han, A. Gojani, and J. Yoh, Appl. Phys. A, 98, No. 1, 147–151 (2010).
T. Lippert, L. Urech, R. Fardel, M. Nagel, C. R. Phipps, and A. Wokaun, Proc. SPIE, 7005, 700512-10 (2008).
E. Yu. Loktionov, Yu. S. Protasov, and Yu. Yu. Protasov, Opt. Spektrosk., 115, No. 5, 152–158 (2013).
C. Phipps, M. Birkan, W. Bohn, H.-A. Eckel, H. Horisawa, T. Lippert, M. M. Michaelis, Y. Rezunkov, A. Sasoh, W. Schall, S. Scharring, and J. Sinko, J. Propuls. Power, 26, No. 4, 609–637 (2010).
E. Yu. Loktionov, Yu. S. Protasov, and Yu. Yu. Protasov, Zh. Prikl. Spektrosk., 80, No. 2, 257–265 (2013).
E. Yu. Loktionov, A. V. Ovchinnikov, Yu. Yu. Protasov, and D. S. Sitnikov, Pis′ma Zh. Tekh. Fiz., 36, No. 13, 8–15 (2010).
L. Urech, T. Lippert, C. R. Phipps, and A. Wokaun, Appl. Surf. Sci., 253, No. 19, 7646–7650 (2007).
J. Sinko, V. Mukundarajan, S. Porter, L. Kodgis, C. Kemp, J. Lassiter, J. Lin, and A. V. Pakhomov, Proc. SPIE, 6261, 626131–12 (2006).
E. Clark, An Innovative Way to Print: Ultra Violet and Electron Beam Curing, Rochester Institute of Technology, New York (2009).
C. Decker and C. Bianchi, J. Mater. Sci., 40, 5491–5497 (2005).
J. Sinko, ″Vaporization and Shock Wave Dynamics for Impulse Generation in Laser Propulsion,″ Ph.D. Dissertation, University of Alabama, Huntsville (2008).
E. Yu. Loktionov, A. V. Ovchinnikov, Yu. Yu. Protasov, and D. S. Sitnikov, Dokl. RAN, 434, No. 1, 38–41 (2010).
E. Yu. Loktionov and Yu. Yu. Protasov, Teplofi z. Vys. Temp., 49, No. 1, 36–44 (2011).
E. Yu. Loktionov and Yu. Yu. Protasov, Prib. Tekh. Éksp., No. 4, 145–149 (2010).
Author information
Authors and Affiliations
Corresponding author
Additional information
Translated from Zhurnal Prikladnoi Spektroskopii, Vol. 81, No. 2, pp. 309–312, March–April, 2014.
Rights and permissions
About this article
Cite this article
Loktionov, E.Y. Study of Laser Ablation Efficiency for an Acrylic-Based Photopolymerizing Composition. J Appl Spectrosc 81, 305–308 (2014). https://doi.org/10.1007/s10812-014-9927-4
Received:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10812-014-9927-4