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In this work a review of investigations concerning interaction of intense extreme ultraviolet (EUV) and soft X-ray (SXR) pulses with matter is presented. The investigations were performed using laser-produced plasma (LPP) EUV/SXR sources based on a double stream gas puff target. The sources are equipped with dedicated collectors allowing for efficient focusing of the EUV/SXR radiation pulses. Intense radiation in a wide spectral range, as well as a quasi-monochromatic radiation can be produced. In the paper different kinds of LPP EUV/SXR sources developed in the Institute of Optoelectronics, Military University of Technology are described. Radiation intensities delivered by the sources are sufficient for different kinds of interaction experiments including EUV/SXR induced ablation, surface treatment, EUV fluorescence or photoionized plasma creation. A brief review of the main results concerning this kind of experiments performed by author of the paper are presented. However, since the LPP sources cannot compete with large scale X-ray sources like synchrotrons, free electron lasers or high energy density plasma sources, it was indicated that some investigations not requiring extreme irradiation parameters can be performed using the small scale installations. Some results, especially concerning low temperature photoionized plasmas are very unique and could be hardly obtained using the large facilities.
Wydawca
Czasopismo
Rocznik
Tom
Strony
172--186
Opis fizyczny
Bibliogr. 62 poz., il., wykr.
Twórcy
autor
- Institute of Optoelectronics, Military University of Technology, 2 Kaliskiego St., 00-908 Warsaw, Poland
Bibliografia
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- 27. A. Bartnik, H. Fiedorowicz, R. Jarocki, J. Kostecki, M. Szczurek, and P.W. Wachulak, “Efficient micromachining of poly(vinylidene fluoride) using a laser-plasma EUV source”, Appl. Phys. A 106, 551-555 (2012).
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- 34. E. Morikawa, J. Choi, and H.M. Manohara, “Photoemission study of direct photomicromachining in poly(vinylidene fluoride)”, J. Appl. Phys. 87, 4010-4016 (2000).
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- 36. Y. Liu and Y. Jiang, “Rapid fabrication of patterned high-performance conductor poly(vinylidene fluoride) surfaces using a 248nm excimer laser”, Opt. Express 18, 22041 (2010).
- 37. L. Bacakova, V. Mares, V. Lisa, and V. Svorcik, “Molecular mechanisms of improved adhesion and growth of an endothelial cell line cultured on polystyrene implanted with fluorine ions”. Biomaterials 21, 1173-1179 (2000).
- 38. M. Collaud Coen, R. Lehmann, P. Groening, and L. Schlapbach, “Modification of the micro- and nanotopography of several polymers by plasma treatments”, Appl. Surf. Sci. 207, 276-286 (2003).
- 39. T. Lippert, “Laser Application of Polymers”, Adv. Polym. Sci. 168, 51-246 (2004).
- 40. T. Gumpenberger, J. Heitz, D. Bauerle, H. Kahr, I. Graz, C. Romanin, V. Svorcik, and F. Leisch, “Adhesion and proliferation of human endothelial cells on photoehemieally modified polytetrafluoroethylene”, Biomaterials 24, 5139-5144 (2003).
- 41. R. Mikulikova, S. Moritz, T. Gumpenberger, M. Olbrich, C. Romanin, L. Bacakova, V. Svorcik, and J. Heitz, “Cell microarrays on photoehemieally modified polytetrafluoroethylene”, Biomaterials 26, 5572-5580 (2005).
- 42. A. Bartnik, H. Fiedorowicz, R. Jarocki, J. Kostecki, A. Szczurek, and M. Szczurek, “Ablation and surface modifications of PMMA using a laser-plasma EUV source”, Appl. Phys. B96, 727-730 (2009).
- 43. A. Bartnik, H. Fiedorowicz, R.Jarocki, J. Kostecki, M. Szczurek, A. Biliński, O. Chemyayeva, and J.W. Sobczak, “Physical and chemical modifications of PET surface using a laser-plasma EUV source”, Appl. Phys. A99, 831 (2010).
- 44. A. Bartnik, H. Fiedorowicz. R. Jarocki, J. Kostecki, M. Szczurek, O. Chemyayeva, and J.W. Sobczak, “EUV-induced physic-chemical changes in near-surface layers of polymers” , J. Electron Spectrosc. Relat. Phenom. 184, 270-275 (2011).
- 45. A. Bartnik, H. Fiedorowicz, R.Jarocki, J. Kostecki, and M. Szczurek, “PMMA and FEP surface modifications induced with EUV pulses in two selected wavelength ranges”, Appl. Phys. A 98, 61-65 (2010).
- 46. A. Bartnik, H. Fiedorowicz, S. Burdyńska, R. Jarocki, J. Kostecki, and M. Szczurek, “Combined effect of EUV irradiation and acetone treatment on PET surface”, Appl. Phys. A103, 173-178 (2011).
- 47. B. Reisinger, M. Fahrner, 1. Frischauf, S. Yakunin, V. Svorcik, H. Fiedorowicz, A. Bartnik, C. Romanin, and J.Heitz, “EUV micropatterning for biocompatibility control of PET”, Appl. Phys. A100, 511-516 (2010).
- 48. A. Bartnik, W. Lisowski, J.Sobczak, P.B. Budner, B. Korczyc, and H. Fiedorowicz, “Simultaneous treatment of polymer surface by EUV radiation and ionized nitrogen”, Appl. Phys. A109, 39-43 (2012).
- 49. A. Bartnik, H. Fiedorowicz, R. Jarocki, J. Kostecki, A.Szczurek, M. Szczurek, P. Wachulak, and L. Pina, “X-ray optics for laser-plasma sources: applications of intense SXR and EUV radiation pulses”, Proc. AIP Conf. 1437, 126 (2012).
- 50. A. Bartnik, H. Fiedorowicz, R. Jarocki, J. Kostecki, R. Rakowski, and M. Szczurek, “Surface changes of solids under intense EUV irradiation using a laser-plasma source”, Proc. SPIE 7361, 73610C (2009).
- 51. A. Bartnik, H. Fiedorowicz, R. Jarocki, J. Kostecki, M.Szczurek, R. Havlikova, L. Pina, L. Sveda, and A. Inneman, “Response of inorganic materials to laser - plasma EUV radiation focused with a lobster eye collector”, Proc. SPIE 6586, 65860A (2007).
- 52. A. Bartnik. H. Fiedorowicz, R. Jarocki, J. Kostecki, R. Rakowski, and M. Szczurek, “EUV emission from solids illuminated with a laser-plasma EUV source”, Appl. Phys. B93, 737-741 (2008).
- 53. R.C. Mancini, J.E. Bailey, J.F. Hawley, T. Kallman, M. Witthoeft, S.J. Rose, H. Takabe, : Accretion disk dynamics, photoionized plasmas, and stellar opacities”, Phys. Plasmas 16,041001 (2009).
- 54. A. Kinkhabwala. M. Sako, E. Behar, S. Kahn, F. Paerels, A. Brinkman, J. Kaastra, M. Gu, and D. Liedahl, “XMM-Newton reflection grating spectrometer observations of discrete soft X-ray emission features from NGC 1068”, Astrophys. J. 575, 732-746 (2002).
- 55. R.C. Mancini, J.E. Bailey, J.F. Hawley, T. Kallman, M. Witthoeft, S.J. Rose, and H. Takabe, “Accretion disk dynamics, photoionized plasmas, and stellar opacities”, Phys. Plasmas 16, 041001 (2009).
- 56. A. Bartnik, P. Wachulak. H. Fiedorowicz, R. Jarocki, J. Kostecki. and M. Szczurek. “Luminescence of He and Ne gases induced by EUV pulses from a laser plasma source”, Radiat. Phys. Chem. 93. 9-13 (2013).
- 57. A. Bartnik, R. Fedosejevs, P. Wachulak, H. Fiedorowicz, C. Serbanescu, E.G. Saiz, D. Riley, S. Toleikis, and D. Neely “Photo-ionized neon plasmas induced by radiation pulses of a laser-plasma EUV source and a free electron laser FLASH”, Laser Part. Beams 31, 195-201 (2013).
- 58. A. Bartnik, H. Fiedorowicz, and P. Wachulak, “Spectral investigations of photoionized plasmas induced in atomic and molecular gases using nanosecond extreme ultraviolet (EUV) pulses”, Phys. Plasmas 21, 073303 (2014).
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- 60. P.L. Bartlett and A.T. Stelbovics, “Calculation of electron-impact total-ionization cross sections”, Phys. Rev. A66, 012707 (2002).
- 61. A. Bartnik, H. Fiedorowicz, T. Fok, R. Jarocki, M. Szczurek, and P. Wachulak, “Low temperature photoionized Ne plasmas induced by laser-plasma EUV sources”, to be published in Laser and Particle Beams.
- 62. A. Bartnik, P. Wachulak, H. Fiedorowicz, T. Fok, R. Jarocki, and M. Szczurek, “Detection of significant differences between absorption spectra of neutral helium and low temperature photoionized helium plasmas”, Phys. Plasmas 20. 113302 (2013).
Uwagi
EN
This work was supported by the grant UMO-2013/09/B/ST2/01625 of the National Science Centre, Poland, by the European Commission’s Seventh Framework Program (LASERLAB-EUROPE), by EU from EUROPEAN REGIONAL DEVELOPMENT FUND, project number: WND-POiG02.01.00-14-095/09.
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Bibliografia
Identyfikator YADDA
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