Pii: S0969-806X(01)00487-X
particles at different stopping powers and ion doses
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particles at different stopping powers and ion doses is investigated. Obtained results for ion beams are presented and discussed. 2. Experimental The investigated organic polymer is chemically represented by (C 9 H 10 ) n monomer chains, has a density of 1.032 g/cm 3 , shows an emission light in the visible region with a maximum at 423 nm wavelength, has a luminescence decay time of 2.5 ns and an attenuation length of 250 cm. Table 1 reports the main physical properties of the polymer. Radiation damage in PVTsamples has been obtained by irradiation with different ions at energies ranging between 50 and 400 keV. Protons and helium beams have been employed for their low stopping powers, and argon and xenon beams for their high stopping powers. The irradiation has been performed at the Ion Implanter Laboratory (IIL) of the Physics Department of Catania University. Irradiation occurs in vacuum (10 7 Torr) in a chamber provided by a mass quadrupole spectrometer (MQS) to detect ‘‘in situ’’ the species desorbed from the polymer. Fig. 1 shows a scheme of the experimental set-up. The MQS spectrometer detects in the range 1–100 amu. *Tel.: +39-090-6765052; fax: +39-090-395004. E-mail address: lorenzo.torrisi@unime.it (L. Torrisi). 0969-806X/01/$ - see front matter r 2001 Elsevier Science Ltd. All rights reserved. PII: S 0 9 6 9 - 8 0 6 X ( 0 1 ) 0 0 4 8 7 - X In order to investigate the radiation damage produced in PVTas a function of the stopping power and ion dose, the luminescence yield induced by proton beams has been detected. Proton beams have been accelerated up to 60 MeV at PSI Laboratory of Zurich, at 24 MeV at INFN-LNS of Catania and within 50–350 keV at IIL of Catania. The luminescence yield has been detected coupling the scintillator to a photo-multiplier (Hamamatsu H5783) having the maximum sensitivity at 430 nm and monitor- ing the output signal with a fast amplifier, ADC converter and MCA multi-channel analyzer, as dis- cussed in the previous paper (Torrisi et al., 1997a). The PVT emission spectra have been investigated as a function of the irradiation stopping power and an ion dose using a spectrophotometer excited at 300 nm wavelength and recording the luminescence in the wavelength region 300–600 nm. Stopping powers and ion ranges have been calculated using the computerized TRIM simulation programs (Ziegler et al., 1985). 3. Results and discussion Fig. 2 reports the experimental results about the luminescence yield as a function of proton stopping powers. At about 2.5 keV/mm stopping, saturation occurs, as a result of significant quenching phenomena due to non-radiative de-excitations (Torrisi, 1998). PVTshows a strong dehydrogenation and an emission of different C x H y groups with the absorbed dose. Fig. 3 reports a mass spectra comparison for the main ejection occurring at masses 2, 26 and 41, corresponding to the emission of H 2 , C 2 H 2 and C 3 H 5 , respectively. The ejection of mass 2 is about one order of magnitude higher than mass 26 and about 25 times higher than mass 41. The kinetics of molecular emission of masses 26 and 41 is slower and it appears very different with respect to the mass 2 emission, which is very fast. From the transient signal, obtained just after the beam switch off, it is possible to observe that by increasing the detected mass the MQS delay time increases. These results demonstrate that a high rate of formation and recombination of free radicals is pro- duced along the ion path in the polymer and a diffusion process of the recombined species occurs towards the polymer surface. Using the MQS calibration procedure, as given in a previous paper (Torrisi, 1999), has been possible to evaluate the ejection yield in terms of the number of ejected molecules per 100 eV incident energy (chemical yield). The experimental chemical yields are 1, 0.1 and 0.03 molecules/100 eV, for masses 2, 26 and 41, respec- tively. The residual polymer contains more and more carbon with the irradiation dose. Generally, a dose of 10 14 ions/cm 2 of 100 keV helium beam produces a black color of the polymer. In terms of the absorbed dose this value corresponds to about 10 MGy. Ion beam Shutter (Faraday cup) PVT Holder MQS Pump system Fig. 1. Experimental setup. 0 20 40 60 80 100 1 2 Yüklə 146,57 Kb. Dostları ilə paylaş:
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