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Polymer Bulletin

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21-12-2019 | Original Paper

Effect of 60 keV argon ion implantation in Makrofol^® DE 1-1 on the optical properties

Authors: Hossam Donya, Abeer Salah

Published in: Polymer Bulletin | Issue 12/2020

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Abstract

Ion implantation in polymeric materials has recently attracted considerable attention in various technology and science fields. The effect of 60 keV low-energy and high-fluence argon ion implantation in the Makrofol^® DE 1-1 polymer on the nonlinear and linear optical properties was investigated. Structural changes of the polymer were studied with Raman spectroscopy to ensure the structural modifications induced by argon ions. Linear optical parameters such as the absorption and refractive index were investigated for the ion-implanted sheets. Direct and indirect optical band gaps were observed to decrease with an increase in argon ion fluence. In addition, an increase in the optical conductivity was found with increasing number of ions implanted in the sheets. The photoluminescence (PL) measurements reveal enhanced PL intensity of higher-fluence ion implanted in contrast to the PL of lower ion implantation fluence. Additionally, nonlinear absorption and optical limiting were investigated via the Z scan technique. The implanted materials have saturable nonlinear absorption, the nonlinear absorption coefficients and the figure of merit were calculated for the investigated samples, and the results show that the implanted argon ion Makrofol is a good candidate for saturable absorbers, optoelectronic devices and medical products.

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Guenther M, Gerlach G, Suchaneck G, Sahre K, Eichhorn K-J, Wolf B, Deineka A, Jastrabik L (2002) Ion-beam induced chemical and structural modification in polymers. Surf Coat Tech 158:108–113

Odzhaev VB, Kozlov IP, Popok VN, Sviridov DV (1998) Ion Implantation Of Polymers. Belorussian State University, Minsk

Wei L, Chen Q, Gu Y (2010) Preparation and characterization of transparent PANI-SIO₂ hybrid conducting films. Polym Eng Sci 50(5):986–990

Das A, Bera S, Dhara S, Patnaik A (1998) Physical and chemical implications of 100 keV H + implantation of laser ablated PPS thin films. Nucl Instrum Methods B 134(3–4):377–384

Hareesh K, Sanjeev G (2019) Effects of radiations on the properties of polycarbonate. In: Kumar V, Chaudhary B, Sharma V, Verma K (eds) Radiation effects in polymeric material. Springer, Cham, pp 293–318

Helal AG, Nouh SA, El-Khabeary H (2015) Structural changes of Makrofol polymer due to argon ion beam irradiation. J Nucl Ene Sci Power Generat Technol 4(1):2

Tripathy SP, Mishra R, Khathing DT, Kulshrestha A, Dwivedi KK, Srivastava A, Ghosh S, Fink D (2001) Optical absorption studies in heavy ion irradiated polymers. Radiat Eff Defect Solids 153:335–341

Stepanov AL (2004) Optical properties of metal nanoparticles synthesized in a polymer by ion implantation: a review. Tech Phys 49(2):143–153

Bityurin N, Alexandrov A, Afanasiev A, Agareva N, Pikulin A, Sapogova N, Smirnova L (2013) Photoinduced nanocomposites—creation, modification, linear and nonlinear optical properties. Appl Phys A 112(1):135–138

10.

Smirnov AB, Savkina RK, Nasieka IM, Strelchuk VV, Demchenko IN, Kryshtab T (2018) Optical characterization of the HgCdTe-based composite structure obtained by Ag ion implantation. J Mater Sci: Mater Electr 29(18):15708–15714

11.

Qiu F, Narusawa T (2011) Application of swift and heavy ion implantation to the formation of chalcogenide glass optical waveguides. Optic Mater 33(3):527–530

12.

Jubera M, Villarroel J, García-Cabañes A, Carrascosa M, Olivares J, Agullo-López F, Ramiro JB (2012) Analysis and optimization of propagation losses in LiNbO₃ optical waveguides produced by swift heavy-ion irradiation. Appl Phys B 107(1):157–162

13.

Jia CL, Li S, Song XX (2017) Optical and structural properties of Nd: MgO: LiNbO₃ crystal irradiated by 2.8-MeV He ions. Appl Phys B 123(7):206

14.

Litrico G, Zimbone M, Baratta G, Marino ADM, Musumeci P (2010) Point defects reactions in ion irradiated SiC. Nucl Inst Methods Phys Res B 268(19):2947–2950

15.

Li B, Xiang X, Liao W, Han S, Yu J, Jiang X, Fu Y (2019) Improved laser induced damage thresholds of Ar ion implanted fused silica at different ion fluences. Appl Surf Sci 471:786–794

16.

Zdorovets MV, Kozlovskiy AL (2018) Argon ion irradiation effect on Zn nanotubes. J Mater Sci: Mater Electr 29(5):3621–3630

17.

Bérerd N, Moncoffre N, Chevarier A, Jaffrézic H, Faust H, Balanzat E (2006) Study of the zirconium oxidation under heavy ion irradiation. Nucl Inst Methods Phys Res B 249(1–2):513–516

18.

Ziegler JF, Ziegler MD, Biersack JP (2010) SRIM–The stopping and range of ions in matter. Nucl Inst Methods Phys Res B 268(11–12):1818–1823

19.

Kondyurin A, Bilek M (2014) Ion beam treatment of polymers: application aspects from medicine to space, 2nd edn. Elsevier, Amsterdam

20.

Hnatowicz V, Fink D (2004) Fundamental of ion irradiated polymers. Springer, Berlin

21.

Stuart BH, Thomas PS (1995) Xylene swelling of polycarbonate studied using Fourier transform Raman spectroscopy. Spectrochim Acta A Mol Biomol Spectrosc 51(12):2133–2137

22.

Goyal PK, Kumar V, Gupta R, Mahendia S, Kumar S (2012) Modification of polycarbonate surface by Ar⁺ ion implantation for various optoelectronic applications. Vacuum 86(8):1087–1091

23.

Nouh SA, Amer H, Remon SW (2009) Effect of neutron dose on the structural properties of Makrofol polycarbonate. Nucl Inst Methods Phys Res B 267(7):1129–1134

24.

Sharma T, Aggarwal S, Sharma A, Kumar S, Kanjilal D, Deshpande SK, Goyal PS (2007) Effect of nitrogen ion implantation on the optical and structural characteristics of CR-39 polymer. J Appl Phys 102(6):063527

25.

Valenza A, Visco AM, Torrisi L, Campo N (2004) Characterization of ultra-high-molecular-weight polyethylene (UHMWPE) modified by ion implantation. Polymer 45(5):1707–1715

26.

Lee EH (1999) Ion-beam modification of polymeric materials–fundamental principles and applications. Nucl Inst Methods Phys Res B 151(1–4):29–41

27.

Lal S, Quamara JK (2014) Effects of 100 MeV O⁷⁺ ion beam irradiation on the optical, chemical and structural properties of NCO-terminated polybutadiene based liquid crystalline polyurethane. Vacuum 105:7–10

28.

Chen JS, Lau SP, Sun Z, Tay BK, Yu GQ, Zhu FY, Xu HJ (2001) Structural and mechanical properties of nitrogen ion implanted ultrahigh molecular weight polyethylene. Surf Coat Technol 138(1):33–38

29.

Mallick B, Patel T, Behera RC, Sarangi SN, Sahu SN, Choudhury RK (2006) Microstrain analysis of proton irradiated PET microfiber. Nucl Inst Methods Phys Res B 248(2):305–310

30.

Donya H, Taha TA (2018) Preparation, structure and optical properties of ZnTe and PbTe nanocrystals grown in fluorophosphate glass. J Mater Sci: Mater Electr 29(10):8610–8616

31.

Donia H, El-Hofy M, El- Samman H, Hussein AA, Rammah Y, Shehata M (2015) Etching and Optical Properties of Gamma Irradiated Makrofol DE 1-1 Nuclear Track. J Nucl Res Dev 10:59–62

32.

Taha TA (2019) Optical properties of PVC/Al₂O₃ nanocomposite films. Polym Bull 76(2):903–918

33.

Fink D, Klett R, Chadderton LT, Cardoso J, Montiel R, Vazquez H, Karanovich AA (1996) Carbonaceous clusters in irradiated polymers as revealed by small angle X-ray scattering and ESR. Nucl Inst Methods Phys Res B 111(3–4):303–314

34.

Taha TA, Hendawy N, El-Rabaie S, Esmat A, El-Mansy MK (2018) Effect of NiO NPs doping on the structure and optical properties of PVC polymer films. Polym Bull 76:1–16

35.

El Sayed AM, El-Sayed S, Morsi WM, Mahrous S, Hassen A (2014) Synthesis, characterization, optical, and dielectric properties of polyvinyl chloride/cadmium oxide nanocomposite films. Polym Compos 35(9):1842–1851

36.

Abdel-Baset T, Elzayat M, Mahrous S (2016) Characterization and optical and dielectric properties of polyvinyl chloride/silica nanocomposites films. Int J Polym Sci 2016:1–10

37.

Yakuphanoglu F, Barım G, Erol I (2007) The effect of FeCl 3 on the optical constants and optical band gap of MBZMA-co-MMA polymer thin films. Phys Rev B: Condens Matter 391(1):136–140

38.

Abdul Nabi M, Yusop RM, Yousif E, Abdullah BM, Salimon J, Salih N, Zubairi SI (2014) Effect of nano ZnO on the optical properties of poly (vinyl chloride) films. Int J Polym Sci 2014:697–809

39.

Swanepoel R (1983) Determination of the thickness and optical constants of amorphous silicon. J Phys E: Sci Instrum 16(12):1214

40.

Kohoutek T, Orava J, Sawada T, Fudouzi H (2011) Inverse opal photonic crystal of chalcogenide glass by solution processing. J Colloid Interface Sci 353(2):454–458PubMed

41.

Leguijt C, Lölgen P, Eikelboom JA, Weeber AW, Schuurmans FM, Sinke WC, Verhoef LA (1996) Low temperature surface passivation for silicon solar cells. Sol Energy Mater Sol Cells 40(4):297–345

42.

Oubaha M, Elmaghrum S, Copperwhite R, Corcoran B, McDonagh C, Gorin A (2012) Optical properties of high refractive index thin films processed at low-temperature. Opt Mater 34(8):1366–1370

43.

Cusano A, Iadicicco A, Paladino D, Campopiano S, Cutolo A, Giordano M (2007) Micro-structured fiber Bragg gratings. Part II: towards advanced photonic devices. Opt Fiber Technol 13:291–301

44.

Wemple SH, DiDomenico M Jr (1971) Behavior of the electronic dielectric constant in covalent and ionic materials. Phys Rev B 3(4):1338

45.

Yakuphanoglu F, Cukurovali A, Yilmaz I (2004) Determination and analysis of the dispersive optical constants of some organic thin films. Phys B 351(1–2):53–58

46.

Sakr GB, Yahia IS, Fadel M, Fouad SS, Romčević N (2010) Optical spectroscopy, optical conductivity, dielectric properties and new methods for determining the gap states of CuSe thin films. J Alloys Compd 507(2):557–562

47.

Fadel M, Fayek SA, Abou-Helal MO, Ibrahim MM, Shakra AM (2009) Structural and optical properties of SeGe and SeGeX (X = In, Sb and Bi) amorphous films. J Alloys Comp 485(1):604–609

48.

Park WD (2012) Optical constants and dispersion parameters of CdS thin film prepared by chemical bath deposition. Trans Electr Electron mater 13(4):196–199

49.

Ziegler JF (2012) Ion implantation science and technology. Elsevier, Amsterdam

50.

Rothberg LJ, Yan M, Papadimitrakopoulos F, Galvin ME, Kwock EW, Miller TM (1996) Photophysics of phenylenevinylene polymers. Synth Metals 80(1):41–58

51.

Charles A (1960) Atomic radiation and polymers. Pergamon Press, Oxford

52.

Tsvetkova T, Balabanov S, Avramov L, Borisova E, Angelov I, Sinning S, Bischoff L (2009) Photoluminescence enhancement in Si + implanted PMMA. Vacuum 83:S252–S255

53.

Sheik-Bahae M, Said AA, Wei TH, Hagan DJ, Van Stryland EW (1990) Sensitive measurement of optical nonlinearities using a single beam. IEEE J Quantum Electron 6(4):760–769

54.

Sankar P, Philip R (2018) Nonlinear optical properties of nanomaterials. In: Bhagyaraj SM, Oluwafemi OS, Kalarikkal N, Thomas S (eds) Characterization of nanomaterials. Woodhead Publishing, Amsterdam, pp 301–334

55.

Huang J, Dong N, Zhang S, Sun Z, Zhang W, Wang J (2017) Nonlinear absorption induced transparency and optical limiting of black phosphorus nanosheets. ACS Photonics 4(12):3063–3070

Title: Effect of 60 keV argon ion implantation in Makrofol® DE 1-1 on the optical properties
Authors: Hossam Donya
Abeer Salah
Publication date: 21-12-2019
Publisher: Springer Berlin Heidelberg
Published in: Polymer Bulletin / Issue 12/2020
Print ISSN: 0170-0839
Electronic ISSN: 1436-2449
DOI: https://doi.org/10.1007/s00289-019-03072-8

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