Home Sapphire irradiation by phosphorus as an approach to improve its optical properties
Article Open Access

Sapphire irradiation by phosphorus as an approach to improve its optical properties

  • Baseerat Bibi EMAIL logo , Ishaq Ahmad , Javaid Hussain , Ziyad Awadh Alrowaili , Ting-kai Zhao , Waseem ur Rahman and Samson O. Aisidia
Published/Copyright: April 5, 2022
Download Article (PDF)
Open Physics
From the journal Open Physics Volume 20 Issue 1

Abstract

Ion beam-induced luminescence (IBIL) is a versatile technique used to elucidate the chemical bond’s nature and analyze the defects study and impurities present in the material. In this study, IBIL spectra of phosphorus-irradiated sapphire has been analyzed under 2 MeV proton beam as a function of ion dose ranging from 1 × 1014 to 10 × 1014 ions/cm2 at room temperature in the wavelength range of 200–1,000 nm. The IBIL spectrum shows three kinds of luminescence features. The bands centered at 419 nm as F center and 330 nm as F+ center are associated with oxygen vacancies. The third kind of luminescence feature located at 704 nm is related to chromium impurities present in the crystal. The luminescence spectrum of the phosphorus-irradiated sapphire has been correlated with the spectrum obtained from pristine sapphire. The finding indicates that the intensity of defects due to phosphorus irradiation is reduced. As the proton ion fluence increases, the F and F+ center luminescence intensity eventually varies; it turns out that in phosphorus-irradiated sapphire, single crystal defects were reduced and the optical quality was improved.

Keywords: single crystal sapphire; ion beam-induced luminescence; proton beam; defects ratio

1 Introduction

Sapphire (α-Al2O3), a good insulator with wide bandgap oxide of about 9 eV, has a wide variety of technological applications because of its unique physical and chemical properties. Due to their high electrical resistance and excellent radiation resistance, they are used as a substrate for integrated microcircuits operating in nuclear power plants and space [1,2]. Optical and luminescent spectroscopy techniques are commonly used to investigate defects of different natures in wide bandgap materials [3,4]. In sapphire, corpuscular irradiation causes point and extended defects that modify their optical properties. The ion beam-induced defect centers in sapphire are mostly F center, F+ center, F2 center, F2+ center, and F22+ center. Thus, the luminescence band located at 415, 330, 518, 385, and 550 nm are related to these centers, respectively [5,6].

Ion beam-induced luminescence (IBIL) is a versatile technique for measuring defects in materials [7,8]. The ion beam is accelerated with high energy that can penetrate up to several microns in most of the materials and give defects and depth profile information. This leads to the critical difference of IBIL from other techniques [9,10,11]. IBIL is complementary to other techniques like photoluminescence (PL) and UV-visible absorption techniques because of its capability to describe point defect mechanism and damage rate in materials [12]. The IBIL of sapphire with an ion beam of different energies and masses under prolonged irradiation has been studied in the literature [13,14,15,16,17,18]. In the practical application, Jardin et al. used IBIL to study the luminescence spectra of sapphire by bombarding different ion species i.e., He+ and H+ irradiation [19]. Also, Aoki et al. studied the sapphire and ruby (α-Al2O3:Cr, Cr2O3 content 0.02%) luminescence spectra by bombarding 200 keV He+ and Ar+ ion beam at room temperature and discussed the defects and their growth and decay [20]. Furthermore, Malo et al. studied IBIL and surface electrical conductivity for three types of alumina by in situ measurement to find a correlation between light emissions and enhanced surface conductivity [21]. Moreover, Crespillo et al. developed a new IBIL system to provide in situ measurements of materials with different ion beams. The real-time, in situ ionoluminescence of SiO2, crystalline quartz, and Al2O3 has been studied to obtained information about the interpretation of luminescence with increasing ion fluences at room temperature [14]. Epie et al. studied the rate of F-center formation with fluence in 170 keV Ar+ irradiated single crystals of α-Al2O3 at room temperature using ion luminescence and found that the rate of F center formation is due to a dynamic competition between defect formation and recombination, with F center saturation corresponding to an equilibrium state between defect formation and recombination [22]. Harutyunya has used photoluminescence spectroscopy to compare the luminescence and electronic properties of electron and neutron-irradiated Al2O3 single crystals with those of unirradiated sapphire crystals to demonstrate the defect behavior of single-crystal sapphire [23]. However, only limited work was reported with the study of ion beam induced defects formed in phosphorus-irradiated sapphire. The use of IBIL is highly efficient to detect defects in materials and has not yet been fully explored.

In this article, the IBIL technique was used for the first time to examine the luminescence of a phosphorus-irradiated sapphire subjected to the irradiation of a hydrogen ion beam that focuses on the behavior of defects such as F+ and F center.

The rest of the article is organized as follows. The experimental setup of IBIL and material preparation are illustrated in Section 2. The results and discussion of our experimental work are presented in Section 3, and the conclusion is given in Section 4 of this article.

2 Materials and methods

The in situ defect study of phosphorus-irradiated single crystal sapphire (α-Al2O3) was conducted with a sample size of about 2.2 mm thickness and 10.0 mm2 × 10.0 mm2 dimension using IBIL at 5 MV Tandem Accelerator at the National Center for Physics, Islamabad, Pakistan. The pristine sapphire single crystal has been procured from the Nuclear Research Centers of Draria, Algeria. The sample has been prepared for the in situ defects study by irradiating pristine single-crystal sapphire with phosphorus ion fluences of 5 × 1015 ions/cm2 at room temperature by 5 MV Tandem Accelerator.

The in situ luminescence spectra of the defective single-crystal sapphire at different proton beam fluences ranging from 1 × 1014 to 10 × 1014 ions/cm2 at 2 MeV at room temperature were examined. Ion beams were focused through collimator and quadrupoles lens. The chamber working as a Faraday cup to measure the total charge impinging on the sample and the specified beam current of 10 nA in a vacuum chamber (10−6 torr). A collimating lens was located at an angle of 45° to the incoming ion beam inside the chamber, which captures the light. Light is then focused on an optical fiber. The vacuum feedthrough guides the light out of the vacuum chamber. Thus, another optical fiber of a larger length is connected with the feedthrough to the outside of the vacuum chamber. The optical fiber then passes light to the ocean FX (QE65000) spectrometer with the entrance slit size of 25 μm, the resolution power of 2 nm, and the wavelength range of collected spectra was 200–1,000 nm. The spectrometer was connected to the PC through a USB cable (RJ45), and data acquisition was controlled by ocean optics software. Figure 1 shows a schematic diagram of the IBIL setup.

Figure 1 Schematic diagram of the IBIL setup.
Figure 1

Schematic diagram of the IBIL setup.

3 Results and discussion

The IBIL spectra of the pristine sapphire at 2 MeV proton beam are presented in Figure 2(a). Three different luminescence bands located at 330, 413, and 705 nm were observed in the measured spectrum. The first two bands represent point defects in sapphire, whereas the third band at 705 nm is related to chromium impurity present in the crystal, as mentioned by Jardin et al. [19]. The band at 330 nm is related to an oxygen vacancy F+ center with a single trap electron, while the band at 414 nm in the spectrum is related to another oxygen vacancy F center with two tarp electrons [24,25]. The IBIL spectrum obtained with 2 MeV H+ ion beam for phosphorus-irradiated sapphire is shown in Figure 2(b). The results showed that the luminescence of phosphorus-irradiated sapphire decreased compared to the pristine sapphire spectrum. It was obtained from the result that after phosphorus irradiation, defects concentration is reduced, as shown in Table 1. This may cause the removal of impurities from the crystal by collision cascade effect by phosphorous ion irradiation and recrystallization of single sapphire crystal to reduce defects due to phosphorous ion beam induced local heating along the ions’ track [26].

Figure 2 IBIL spectra of (a) the pristine sapphire using 2 MeV proton beam and (b) comparison of the pristine and phosphorus-irradiated sapphire.
Figure 2

IBIL spectra of (a) the pristine sapphire using 2 MeV proton beam and (b) comparison of the pristine and phosphorus-irradiated sapphire.

Table 1

Intensity value of F and F+ centers obtained by using a 2 MeV proton beam

Sample Intensity
F+ (Cts/s) F (Cts/s) Cr (Cts/s)
Pristine 941 3,524 352
Phosphorus-irradiated sapphire 196 1,200 155

The luminescence spectra were obtained from phosphorus-irradiated sapphire at proton fluence of 1 × 1014 to 10 × 1014 ions/cm2, as shown in Figure 3. The contribution of the F center to the luminescence spectrum increases as the dose increases, while the luminescence of the F+ band decreases. When the ion dose increases further, the intensity of the F center decreases, while the F+ center increases. This shows the creation and annihilation of the F center and F+ center. This fact indicates that a significant part of the luminescence is due to the defects produced by irradiation and that the intensity of these bands may represent the amounts of the F+ and F centers [27]. Al Ghamdi and Townsend reported a similar irradiation record for the IBIL of sapphire, in which non-zero values were observed for the low-fluence luminescence intensity and indicated that the luminescence is from the intrinsic color centers triggered by the excited electrons [28]. On the other hand, almost zero values have been found for the annealed specimens, suggesting that the luminescence occurs from the centers such as F+ and F produced by the annealed specimens [27]. The radiation fluence often attenuates the Cr+3 peak intensity due to proton beam induced local heating along the beam track, which causes undoped Cr atoms doped in the sapphire crystal. The overall luminescence intensity decreases at greater fluence, which may be due to the development of new defect center F2+ at higher fluence [29].

Figure 3 Luminescence spectra analyses of sapphire with different proton fluences.
Figure 3

Luminescence spectra analyses of sapphire with different proton fluences.

Figure 4(a) and (b) shows the behavior of F center and F+ center as a function of fluence. Initially, the F and F+ center increases, which shows the creation of defects due to ion beam displacement damage. As the ion fluence increases, the decrease in the intensity of the defects is observed that might be due to the degradation and annihilation of these centers [30,31].

Figure 4 (a) Intensity of F center as a function of ion fluence and (b) intensity of F+ center as a function of ion fluence.
Figure 4

(a) Intensity of F center as a function of ion fluence and (b) intensity of F+ center as a function of ion fluence.

According to the results of the in situ study of defective sapphire by proton beam mentioned above, the intensity ratio of I(F)/I(F+) depends on ion fluence as shown in Figure 5. The result revealed that as the ion fluence increases, variation in the intensity ratio was observed. This shows the creation and annihilation of the F center and F+ center; by studying the entire spectrum, the F center is dominant over the F+ center. A similar phenomenon was reported by Skuratov et al. in the case of heavy irradiation; the F center contribution to luminescence is higher due to some F+ center during irradiation following annihilation with interstitial or other defects [10,11]. The intensity ratio between F+ and F is heavily dependent on the dose rate in the study of electron-irradiated sapphire, the luminescence of F+ increases with the dose rate, while the luminescence of F decreases [27,32]. Data reported for heavy-ion by Crespillo et al. and Malo et al. at 45 keV Helium ion, for unirradiated sapphire, showed that it is reasonable to assume interstitial vacancy recombination and vacancy aggregation at the early stage of irradiation [14,31]. Crespillo et al. stated that two F/F+ centers are removed by the creation of each F2+ center and may account for some of the decreases in the signal from a single vacancy center [14]. However, in the present study, no such higher defects were observed, but the overall decrease in the intensity ratio was observed, that is, recrystallization triggered by electronic energy loss by oxygen ions, as stated by Sina et al. [33].

Figure 5 The ratio of (F/F+) emission intensities on proton fluence at 2 MeV.
Figure 5

The ratio of (F/F+) emission intensities on proton fluence at 2 MeV.

4 Conclusion

This article uses the IBIL technique to examine the in situ defects study of phosphorus-irradiated sapphire subjected to the irradiation of a proton beam of 2 MeV at room temperature. The IBIL analysis shows F center, F+ center, and cr3+ luminescence features. The IBIL comparative analysis was presented in pristine sapphire and phosphorus-irradiated sapphire. The observation shows a decrease in the luminescence of defective sapphire to phosphorus irradiation that might be the reason for the removal of impurities from the crystal by collision cascade effect by phosphorous ion irradiation and recrystallization of single sapphire crystal to reduce defects as phosphorous ion beam induced local heating along the ions’ track. It was also observed that the intensity of these luminescence features varies as a function of proton ion fluences. On increasing of the proton ion fluence, the ratio F/F+ gradually increases up to a dose of 3 × 1014 ions/cm2, but on further increase in the proton ion fluence, the ratio F/F+ decreases. It was observed that the creation and annihilation of F and F+ centers occur with varying ion fluence. It turns out to be concluded that defects were reduced in the phosphorus-irradiated sapphire single crystal and the crystal quality was improved. The eventual decrease in the luminescence intensity of F center and F+ center indicates that IBIL is the best tool to monitor in situ material characterization in a high radiation environment to diagnose the inaccessible part of future fusion devices with fission reactors.

  1. Funding information: The authors acknowledge and appreciate the support provided by the National Center of Physics, Islamabad, Pakistan.

  2. Author contributions: All authors have accepted responsibility for the entire content of this manuscript and approved its submission.

  3. Conflict of interest: The authors state no conflict of interest.

  4. Data availability statement: The datasets generated and/or analysed during the current study are not publicly available due to individual privacy but are available from the corresponding author on reasonable request.

References

[1] Ananchenko D, Nikiforov S, Kuzovkov V, Popov A, Ramazanova G, Batalov R, et al. Radiation-induced defects in sapphire single crystals irradiated by a pulsed ion beam. Nucl Instrum Methods Phys Res Sect B: Beam Interact Mater At. 2020;466:1–7.10.1016/j.nimb.2019.12.032Search in Google Scholar

[2] Dobrovinskaya ER, Lytvynov LA, Pishchik V. Sapphire: material, manufacturing, applications. Springer Science & Business Media; 2009.10.1007/978-0-387-85695-7Search in Google Scholar

[3] Evans BD. A review of the optical properties of anion lattice vacancies, and electrical conduction in α-Al2O3: their relation to radiation-induced electrical degradation. J Nucl Mater. 1995;219:202–23.10.1016/0022-3115(94)00529-XSearch in Google Scholar

[4] Seeman V, Lushchik A, Shablonin E, Prieditis G, Gryaznov D, Platonenko A, et al. Atomic, electronic and magnetic structure of an oxygen interstitial in neutron-irradiated Al2O3 single crystals. Sci Rep. 2020;10(1):1–14.10.1038/s41598-020-72958-9Search in Google Scholar

[5] Jheeta K, Jain D, Kumar R, Singh F, Garg K. Photoluminescence study of swift heavy ion (SHI) induced defect centers in sapphire. J Nucl Mater. 2006;353(3):190–2.10.1016/j.jnucmat.2006.01.017Search in Google Scholar

[6] Ananchenko D, Nikiforov S, Ramazanova G, Batalov R, Bayazitov R, Novikov H. Luminescence of F-type defects and their thermal stability in sapphire irradiated by pulsed ion beams. Opt Spectrosc. 2020;128(2):207–13.10.1134/S0030400X20020022Search in Google Scholar

[7] Batool A, Izerrouken M, Aisida SO, Hussain J, Ahmad I, Afzal MQ, et al. Effect of Ca colloids on in situ ionoluminescence of CaF2 single crystals. Nucl Instrum Methods Phys Res Sect B: Beam Interact Mater At. 2020;476:40–3.10.1016/j.nimb.2020.05.005Search in Google Scholar

[8] Batool A, Aisida SO, Hussain J, Honey S, Izerrouken M, Faridi A, et al. In situ investigation of point defects kinetics in LiF using ion luminescence technique. Nucl Instrum Methods Phys Res Sect B: Beam Interact Mater At. 2020;466:52–5.10.1016/j.nimb.2020.01.021Search in Google Scholar

[9] Skuratov V, Gun KJ, Stano J, Zagorski D. In situ luminescence as monitor of radiation damage under swift heavy ion irradiation. Nucl Instrum Methods Phys Res Sect B: Beam Interact Mater At. 2006;245(1):194–200.10.1016/j.nimb.2005.11.100Search in Google Scholar

[10] Skuratov V, AlAzm SA, Altynov V. Luminescence of aggregate centers in lithium fluoride irradiated with high energy heavy ions. Nucl Instrum Methods Phys Res Sect B: Beam Interact Mater At. 2002;191(1–4):251–5.10.1016/S0168-583X(02)00570-0Search in Google Scholar

[11] Skuratov V, Didyk AY, AlAzm SA. In situ investigations of high-energy heavy ion irradiation effects: High-energy ionoluminescence of LiF. Radiat Phys Chem. 1997;50(2):183–8.10.1016/S0969-806X(96)00188-0Search in Google Scholar

[12] Quaranta A, Valotto G, Piccinini M, Montereali R. Ion beam induced luminescence analysis of defect evolution in lithium fluoride under proton irradiation. Optical Mater. 2015;49:1–5.10.1016/j.optmat.2015.08.015Search in Google Scholar

[13] Marković N, Siketić Z, Cosic D, Jung H, Lee N, Han W-T, et al. Ion beam induced luminescence (IBIL) system for imaging of radiation induced changes in materials. Nucl Instrum Methods Phys Res Sect B: Beam Interact Mater At. 2015;343:167–72.10.1016/j.nimb.2014.11.046Search in Google Scholar

[14] Crespillo ML, Graham JT, Zhang Y, Weber WJ. In situ luminescence monitoring of ion-induced damage evolution in SiO2 and Al2O3. J Lumin. 2016;172:208–18.10.1016/j.jlumin.2015.12.016Search in Google Scholar

[15] Toshima R, Miyamaru H, Asahara J, Murasawa T, Takahashi A. Ion-induced luminescence of alumina with time-resolved spectroscopy. J Nucl Sci Technol. 2002;39(1):15–8.10.1080/18811248.2002.9715152Search in Google Scholar

[16] Brooks R, Hole D, Townsend P. Ion beam induced luminescence of materials. Nucl Instrum Methods Phys Res Sect B: Beam Interact Mater At. 2002;190(1–4):136–40.10.1016/S0168-583X(01)01226-5Search in Google Scholar

[17] Mohanty T, Mishra N, Singh F, Tiwari U, Kanjilal D. Swift heavy ion irradiation induced modifications in sapphire. Nucl Instrum Methods Phys Res Sect B: Beam Interact Mater At. 2003;212:179–83.10.1016/S0168-583X(03)01487-3Search in Google Scholar

[18] Zhang L, Zhang X, You W, Yang Z, Wang W, Ge Q, et al. Effects of ion implantation on yellow luminescence in unintentional doped n-type GaN. Open Phys. 2008;6(2):283–8.10.2478/s11534-008-0013-5Search in Google Scholar

[19] Jardin C, Canut B, Ramos S. The luminescence of sapphire subjected to the irradiation of energetic hydrogen and helium ions. J Phys D: Appl Phys. 1996;29(8):2066.10.1088/0022-3727/29/8/002Search in Google Scholar

[20] Aoki Y, My NT, Yamamoto S, Naramoto H. Luminescence of sapphire and ruby induced by He and Ar ion irradiation. Nucl Instrum Methods Phys Res Sect B: Beam Interact Mater At. 1996;114(3–4):276–80.10.1016/0168-583X(96)00186-3Search in Google Scholar

[21] Malo M, Moroño A, Hodgson E. Radioluminescence monitoring of radiation induced surface electrical degradation in aluminas. J Nucl Mater. 2013;442(1–3):S520–3.10.1016/j.jnucmat.2012.11.052Search in Google Scholar

[22] Epie E, Wijesundera D, Tilakaratne B, Chen Q, Chu W. Rate of F center formation in sapphire under low-energy low-fluence Ar+ irradiation. Nucl Instrum Methods Phys Res Sect B: Beam Interact Mater At. 2016;371:303–6.10.1016/j.nimb.2015.09.037Search in Google Scholar

[23] Harutyunyan V, Aleksanyan E, Grigoryan N, Sahakyan A, Yeritsyan G, Nikoghosyan S, et al. Luminescence and dielectric properties of electron and neutron irradiated corundum single crystals. Armen J Phys. 2017;10(2):69–75.Search in Google Scholar

[24] Kittel C, McEuen P, McEuen P. Introduction to solid state physics. New York: Wiley; 1996.Search in Google Scholar

[25] Islamov AK, Ibragimova E, Nuritdinov I. Radiation-optical characteristics of quartz glass and sapphire. J Nucl Mater. 2007;362(2–3):222–6.10.1016/j.jnucmat.2007.01.047Search in Google Scholar

[26] Mekys A, Jurkevičius J, Kadys A, Kolenda M, Kovalevskij V, Tamulaitis G. Influence of proton irradiation on carrier mobility in InN epitaxial layers. Thin Solid Films. 2019;692:137619.10.1016/j.tsf.2019.137619Search in Google Scholar

[27] Moritani K, Teraoka Y, Takagi I, Akiyoshi M, Moriyama H. Production and reaction kinetics of radiation-induced defects in α-alumina and sapphire under ion beam irradiation. J Nucl Mater. 2008;373(1–3):157–63.10.1016/j.jnucmat.2007.06.001Search in Google Scholar

[28] Al Ghamdi A, Townsend P. Ion beam excited luminescence of sapphire. Nucl Instrum Methods Phys Res Sect B: Beam Interact Mater At. 1990;46(1–4):133–6.10.1016/0168-583X(90)90684-MSearch in Google Scholar

[29] Jheeta K, Jain D, Singh F, Kumar R, Garg K. Photoluminescence and UV-vis studies of pre-and post-irradiated sapphire with 200 MeV Ag8+ ions. Nucl Instrum Methods Phys Res Sect B: Beam Interact Mater At. 2006;244(1):187–9.10.1016/j.nimb.2005.11.024Search in Google Scholar

[30] Abdellaoui K, Hager IZ, Othman HA, Boumaza A, Kamoun NT. Structural, optical and thermal characterizations of lithium borate glasses containing the barite. Defect Diffus Forum. 2019;397:24–38.10.4028/www.scientific.net/DDF.397.24Search in Google Scholar

[31] Malo M, Moroño A, Hodgson E. In situ luminescence qualification of radiation damage in aluminas: F-aggregation and Al colloids. Fusion Eng Des. 2014;89(9–10):2179–83.10.1016/j.fusengdes.2014.02.034Search in Google Scholar

[32] Grygiel C, Moisy F, Sall M, Lebius H, Balanzat E, Madi T, et al. In situ kinetics of modifications induced by swift heavy ions in Al2O3: colour centre formation, structural modification and amorphization. Acta Mater. 2017;140:157–67.10.1016/j.actamat.2017.08.028Search in Google Scholar

[33] Sina Y, Ishimaru M, McHargue CJ, Alves E, Sickafus KE. Ion beam induced epitaxial crystallization of α-Al2O3 at room temperature. Nucl Instrum Methods Phys Res Sect B: Beam Interact Mater At. 2014;321:8–13.10.1016/j.nimb.2013.12.012Search in Google Scholar
Received: 2021-07-29
Revised: 2022-03-02
Accepted: 2022-03-08
Published Online: 2022-04-05

© 2022 Baseerat Bibi et al., published by De Gruyter

This work is licensed under the Creative Commons Attribution 4.0 International License.

Articles in the same Issue

  1. Regular Articles
  2. Test influence of screen thickness on double-N six-light-screen sky screen target
  3. Analysis on the speed properties of the shock wave in light curtain
  4. Abundant accurate analytical and semi-analytical solutions of the positive Gardner–Kadomtsev–Petviashvili equation
  5. Measured distribution of cloud chamber tracks from radioactive decay: A new empirical approach to investigating the quantum measurement problem
  6. Nuclear radiation detection based on the convolutional neural network under public surveillance scenarios
  7. Effect of process parameters on density and mechanical behaviour of a selective laser melted 17-4PH stainless steel alloy
  8. Performance evaluation of self-mixing interferometer with the ceramic type piezoelectric accelerometers
  9. Effect of geometry error on the non-Newtonian flow in the ceramic microchannel molded by SLA
  10. Numerical investigation of ozone decomposition by self-excited oscillation cavitation jet
  11. Modeling electrostatic potential in FDSOI MOSFETS: An approach based on homotopy perturbations
  12. Modeling analysis of microenvironment of 3D cell mechanics based on machine vision
  13. Numerical solution for two-dimensional partial differential equations using SM’s method
  14. Multiple velocity composition in the standard synchronization
  15. Electroosmotic flow for Eyring fluid with Navier slip boundary condition under high zeta potential in a parallel microchannel
  16. Soliton solutions of Calogero–Degasperis–Fokas dynamical equation via modified mathematical methods
  17. Performance evaluation of a high-performance offshore cementing wastes accelerating agent
  18. Sapphire irradiation by phosphorus as an approach to improve its optical properties
  19. A physical model for calculating cementing quality based on the XGboost algorithm
  20. Experimental investigation and numerical analysis of stress concentration distribution at the typical slots for stiffeners
  21. An analytical model for solute transport from blood to tissue
  22. Finite-size effects in one-dimensional Bose–Einstein condensation of photons
  23. Drying kinetics of Pleurotus eryngii slices during hot air drying
  24. Computer-aided measurement technology for Cu2ZnSnS4 thin-film solar cell characteristics
  25. QCD phase diagram in a finite volume in the PNJL model
  26. Study on abundant analytical solutions of the new coupled Konno–Oono equation in the magnetic field
  27. Experimental analysis of a laser beam propagating in angular turbulence
  28. Numerical investigation of heat transfer in the nanofluids under the impact of length and radius of carbon nanotubes
  29. Multiple rogue wave solutions of a generalized (3+1)-dimensional variable-coefficient Kadomtsev--Petviashvili equation
  30. Optical properties and thermal stability of the H+-implanted Dy3+/Tm3+-codoped GeS2–Ga2S3–PbI2 chalcohalide glass waveguide
  31. Nonlinear dynamics for different nonautonomous wave structure solutions
  32. Numerical analysis of bioconvection-MHD flow of Williamson nanofluid with gyrotactic microbes and thermal radiation: New iterative method
  33. Modeling extreme value data with an upside down bathtub-shaped failure rate model
  34. Abundant optical soliton structures to the Fokas system arising in monomode optical fibers
  35. Analysis of the partially ionized kerosene oil-based ternary nanofluid flow over a convectively heated rotating surface
  36. Multiple-scale analysis of the parametric-driven sine-Gordon equation with phase shifts
  37. Magnetofluid unsteady electroosmotic flow of Jeffrey fluid at high zeta potential in parallel microchannels
  38. Effect of plasma-activated water on microbial quality and physicochemical properties of fresh beef
  39. The finite element modeling of the impacting process of hard particles on pump components
  40. Analysis of respiratory mechanics models with different kernels
  41. Extended warranty decision model of failure dependence wind turbine system based on cost-effectiveness analysis
  42. Breather wave and double-periodic soliton solutions for a (2+1)-dimensional generalized Hirota–Satsuma–Ito equation
  43. First-principle calculation of electronic structure and optical properties of (P, Ga, P–Ga) doped graphene
  44. Numerical simulation of nanofluid flow between two parallel disks using 3-stage Lobatto III-A formula
  45. Optimization method for detection a flying bullet
  46. Angle error control model of laser profilometer contact measurement
  47. Numerical study on flue gas–liquid flow with side-entering mixing
  48. Travelling waves solutions of the KP equation in weakly dispersive media
  49. Characterization of damage morphology of structural SiO2 film induced by nanosecond pulsed laser
  50. A study of generalized hypergeometric Matrix functions via two-parameter Mittag–Leffler matrix function
  51. Study of the length and influencing factors of air plasma ignition time
  52. Analysis of parametric effects in the wave profile of the variant Boussinesq equation through two analytical approaches
  53. The nonlinear vibration and dispersive wave systems with extended homoclinic breather wave solutions
  54. Generalized notion of integral inequalities of variables
  55. The seasonal variation in the polarization (Ex/Ey) of the characteristic wave in ionosphere plasma
  56. Impact of COVID 19 on the demand for an inventory model under preservation technology and advance payment facility
  57. Approximate solution of linear integral equations by Taylor ordering method: Applied mathematical approach
  58. Exploring the new optical solitons to the time-fractional integrable generalized (2+1)-dimensional nonlinear Schrödinger system via three different methods
  59. Irreversibility analysis in time-dependent Darcy–Forchheimer flow of viscous fluid with diffusion-thermo and thermo-diffusion effects
  60. Double diffusion in a combined cavity occupied by a nanofluid and heterogeneous porous media
  61. NTIM solution of the fractional order parabolic partial differential equations
  62. Jointly Rayleigh lifetime products in the presence of competing risks model
  63. Abundant exact solutions of higher-order dispersion variable coefficient KdV equation
  64. Laser cutting tobacco slice experiment: Effects of cutting power and cutting speed
  65. Performance evaluation of common-aperture visible and long-wave infrared imaging system based on a comprehensive resolution
  66. Diesel engine small-sample transfer learning fault diagnosis algorithm based on STFT time–frequency image and hyperparameter autonomous optimization deep convolutional network improved by PSO–GWO–BPNN surrogate model
  67. Analyses of electrokinetic energy conversion for periodic electromagnetohydrodynamic (EMHD) nanofluid through the rectangular microchannel under the Hall effects
  68. Propagation properties of cosh-Airy beams in an inhomogeneous medium with Gaussian PT-symmetric potentials
  69. Dynamics investigation on a Kadomtsev–Petviashvili equation with variable coefficients
  70. Study on fine characterization and reconstruction modeling of porous media based on spatially-resolved nuclear magnetic resonance technology
  71. Optimal block replacement policy for two-dimensional products considering imperfect maintenance with improved Salp swarm algorithm
  72. A hybrid forecasting model based on the group method of data handling and wavelet decomposition for monthly rivers streamflow data sets
  73. Hybrid pencil beam model based on photon characteristic line algorithm for lung radiotherapy in small fields
  74. Surface waves on a coated incompressible elastic half-space
  75. Radiation dose measurement on bone scintigraphy and planning clinical management
  76. Lie symmetry analysis for generalized short pulse equation
  77. Spectroscopic characteristics and dissociation of nitrogen trifluoride under external electric fields: Theoretical study
  78. Cross electromagnetic nanofluid flow examination with infinite shear rate viscosity and melting heat through Skan-Falkner wedge
  79. Convection heat–mass transfer of generalized Maxwell fluid with radiation effect, exponential heating, and chemical reaction using fractional Caputo–Fabrizio derivatives
  80. Weak nonlinear analysis of nanofluid convection with g-jitter using the Ginzburg--Landau model
  81. Strip waveguides in Yb3+-doped silicate glass formed by combination of He+ ion implantation and precise ultrashort pulse laser ablation
  82. Best selected forecasting models for COVID-19 pandemic
  83. Research on attenuation motion test at oblique incidence based on double-N six-light-screen system
  84. Review Articles
  85. Progress in epitaxial growth of stanene
  86. Review and validation of photovoltaic solar simulation tools/software based on case study
  87. Brief Report
  88. The Debye–Scherrer technique – rapid detection for applications
  89. Rapid Communication
  90. Radial oscillations of an electron in a Coulomb attracting field
  91. Special Issue on Novel Numerical and Analytical Techniques for Fractional Nonlinear Schrodinger Type - Part II
  92. The exact solutions of the stochastic fractional-space Allen–Cahn equation
  93. Propagation of some new traveling wave patterns of the double dispersive equation
  94. A new modified technique to study the dynamics of fractional hyperbolic-telegraph equations
  95. An orthotropic thermo-viscoelastic infinite medium with a cylindrical cavity of temperature dependent properties via MGT thermoelasticity
  96. Modeling of hepatitis B epidemic model with fractional operator
  97. Special Issue on Transport phenomena and thermal analysis in micro/nano-scale structure surfaces - Part III
  98. Investigation of effective thermal conductivity of SiC foam ceramics with various pore densities
  99. Nonlocal magneto-thermoelastic infinite half-space due to a periodically varying heat flow under Caputo–Fabrizio fractional derivative heat equation
  100. The flow and heat transfer characteristics of DPF porous media with different structures based on LBM
  101. Homotopy analysis method with application to thin-film flow of couple stress fluid through a vertical cylinder
  102. Special Issue on Advanced Topics on the Modelling and Assessment of Complicated Physical Phenomena - Part II
  103. Asymptotic analysis of hepatitis B epidemic model using Caputo Fabrizio fractional operator
  104. Influence of chemical reaction on MHD Newtonian fluid flow on vertical plate in porous medium in conjunction with thermal radiation
  105. Structure of analytical ion-acoustic solitary wave solutions for the dynamical system of nonlinear wave propagation
  106. Evaluation of ESBL resistance dynamics in Escherichia coli isolates by mathematical modeling
  107. On theoretical analysis of nonlinear fractional order partial Benney equations under nonsingular kernel
  108. The solutions of nonlinear fractional partial differential equations by using a novel technique
  109. Modelling and graphing the Wi-Fi wave field using the shape function
  110. Generalized invexity and duality in multiobjective variational problems involving non-singular fractional derivative
  111. Impact of the convergent geometric profile on boundary layer separation in the supersonic over-expanded nozzle
  112. Variable stepsize construction of a two-step optimized hybrid block method with relative stability
  113. Thermal transport with nanoparticles of fractional Oldroyd-B fluid under the effects of magnetic field, radiations, and viscous dissipation: Entropy generation; via finite difference method
  114. Special Issue on Advanced Energy Materials - Part I
  115. Voltage regulation and power-saving method of asynchronous motor based on fuzzy control theory
  116. The structure design of mobile charging piles
  117. Analysis and modeling of pitaya slices in a heat pump drying system
  118. Design of pulse laser high-precision ranging algorithm under low signal-to-noise ratio
  119. Special Issue on Geological Modeling and Geospatial Data Analysis
  120. Determination of luminescent characteristics of organometallic complex in land and coal mining
  121. InSAR terrain mapping error sources based on satellite interferometry
https://doi.org/10.1515/phys-2022-0022
Keywords for this article
single crystal sapphire; ion beam-induced luminescence; proton beam; defects ratio
Creative Commons
BY 4.0

Articles in the same Issue

  1. Regular Articles
  2. Test influence of screen thickness on double-N six-light-screen sky screen target
  3. Analysis on the speed properties of the shock wave in light curtain
  4. Abundant accurate analytical and semi-analytical solutions of the positive Gardner–Kadomtsev–Petviashvili equation
  5. Measured distribution of cloud chamber tracks from radioactive decay: A new empirical approach to investigating the quantum measurement problem
  6. Nuclear radiation detection based on the convolutional neural network under public surveillance scenarios
  7. Effect of process parameters on density and mechanical behaviour of a selective laser melted 17-4PH stainless steel alloy
  8. Performance evaluation of self-mixing interferometer with the ceramic type piezoelectric accelerometers
  9. Effect of geometry error on the non-Newtonian flow in the ceramic microchannel molded by SLA
  10. Numerical investigation of ozone decomposition by self-excited oscillation cavitation jet
  11. Modeling electrostatic potential in FDSOI MOSFETS: An approach based on homotopy perturbations
  12. Modeling analysis of microenvironment of 3D cell mechanics based on machine vision
  13. Numerical solution for two-dimensional partial differential equations using SM’s method
  14. Multiple velocity composition in the standard synchronization
  15. Electroosmotic flow for Eyring fluid with Navier slip boundary condition under high zeta potential in a parallel microchannel
  16. Soliton solutions of Calogero–Degasperis–Fokas dynamical equation via modified mathematical methods
  17. Performance evaluation of a high-performance offshore cementing wastes accelerating agent
  18. Sapphire irradiation by phosphorus as an approach to improve its optical properties
  19. A physical model for calculating cementing quality based on the XGboost algorithm
  20. Experimental investigation and numerical analysis of stress concentration distribution at the typical slots for stiffeners
  21. An analytical model for solute transport from blood to tissue
  22. Finite-size effects in one-dimensional Bose–Einstein condensation of photons
  23. Drying kinetics of Pleurotus eryngii slices during hot air drying
  24. Computer-aided measurement technology for Cu2ZnSnS4 thin-film solar cell characteristics
  25. QCD phase diagram in a finite volume in the PNJL model
  26. Study on abundant analytical solutions of the new coupled Konno–Oono equation in the magnetic field
  27. Experimental analysis of a laser beam propagating in angular turbulence
  28. Numerical investigation of heat transfer in the nanofluids under the impact of length and radius of carbon nanotubes
  29. Multiple rogue wave solutions of a generalized (3+1)-dimensional variable-coefficient Kadomtsev--Petviashvili equation
  30. Optical properties and thermal stability of the H+-implanted Dy3+/Tm3+-codoped GeS2–Ga2S3–PbI2 chalcohalide glass waveguide
  31. Nonlinear dynamics for different nonautonomous wave structure solutions
  32. Numerical analysis of bioconvection-MHD flow of Williamson nanofluid with gyrotactic microbes and thermal radiation: New iterative method
  33. Modeling extreme value data with an upside down bathtub-shaped failure rate model
  34. Abundant optical soliton structures to the Fokas system arising in monomode optical fibers
  35. Analysis of the partially ionized kerosene oil-based ternary nanofluid flow over a convectively heated rotating surface
  36. Multiple-scale analysis of the parametric-driven sine-Gordon equation with phase shifts
  37. Magnetofluid unsteady electroosmotic flow of Jeffrey fluid at high zeta potential in parallel microchannels
  38. Effect of plasma-activated water on microbial quality and physicochemical properties of fresh beef
  39. The finite element modeling of the impacting process of hard particles on pump components
  40. Analysis of respiratory mechanics models with different kernels
  41. Extended warranty decision model of failure dependence wind turbine system based on cost-effectiveness analysis
  42. Breather wave and double-periodic soliton solutions for a (2+1)-dimensional generalized Hirota–Satsuma–Ito equation
  43. First-principle calculation of electronic structure and optical properties of (P, Ga, P–Ga) doped graphene
  44. Numerical simulation of nanofluid flow between two parallel disks using 3-stage Lobatto III-A formula
  45. Optimization method for detection a flying bullet
  46. Angle error control model of laser profilometer contact measurement
  47. Numerical study on flue gas–liquid flow with side-entering mixing
  48. Travelling waves solutions of the KP equation in weakly dispersive media
  49. Characterization of damage morphology of structural SiO2 film induced by nanosecond pulsed laser
  50. A study of generalized hypergeometric Matrix functions via two-parameter Mittag–Leffler matrix function
  51. Study of the length and influencing factors of air plasma ignition time
  52. Analysis of parametric effects in the wave profile of the variant Boussinesq equation through two analytical approaches
  53. The nonlinear vibration and dispersive wave systems with extended homoclinic breather wave solutions
  54. Generalized notion of integral inequalities of variables
  55. The seasonal variation in the polarization (Ex/Ey) of the characteristic wave in ionosphere plasma
  56. Impact of COVID 19 on the demand for an inventory model under preservation technology and advance payment facility
  57. Approximate solution of linear integral equations by Taylor ordering method: Applied mathematical approach
  58. Exploring the new optical solitons to the time-fractional integrable generalized (2+1)-dimensional nonlinear Schrödinger system via three different methods
  59. Irreversibility analysis in time-dependent Darcy–Forchheimer flow of viscous fluid with diffusion-thermo and thermo-diffusion effects
  60. Double diffusion in a combined cavity occupied by a nanofluid and heterogeneous porous media
  61. NTIM solution of the fractional order parabolic partial differential equations
  62. Jointly Rayleigh lifetime products in the presence of competing risks model
  63. Abundant exact solutions of higher-order dispersion variable coefficient KdV equation
  64. Laser cutting tobacco slice experiment: Effects of cutting power and cutting speed
  65. Performance evaluation of common-aperture visible and long-wave infrared imaging system based on a comprehensive resolution
  66. Diesel engine small-sample transfer learning fault diagnosis algorithm based on STFT time–frequency image and hyperparameter autonomous optimization deep convolutional network improved by PSO–GWO–BPNN surrogate model
  67. Analyses of electrokinetic energy conversion for periodic electromagnetohydrodynamic (EMHD) nanofluid through the rectangular microchannel under the Hall effects
  68. Propagation properties of cosh-Airy beams in an inhomogeneous medium with Gaussian PT-symmetric potentials
  69. Dynamics investigation on a Kadomtsev–Petviashvili equation with variable coefficients
  70. Study on fine characterization and reconstruction modeling of porous media based on spatially-resolved nuclear magnetic resonance technology
  71. Optimal block replacement policy for two-dimensional products considering imperfect maintenance with improved Salp swarm algorithm
  72. A hybrid forecasting model based on the group method of data handling and wavelet decomposition for monthly rivers streamflow data sets
  73. Hybrid pencil beam model based on photon characteristic line algorithm for lung radiotherapy in small fields
  74. Surface waves on a coated incompressible elastic half-space
  75. Radiation dose measurement on bone scintigraphy and planning clinical management
  76. Lie symmetry analysis for generalized short pulse equation
  77. Spectroscopic characteristics and dissociation of nitrogen trifluoride under external electric fields: Theoretical study
  78. Cross electromagnetic nanofluid flow examination with infinite shear rate viscosity and melting heat through Skan-Falkner wedge
  79. Convection heat–mass transfer of generalized Maxwell fluid with radiation effect, exponential heating, and chemical reaction using fractional Caputo–Fabrizio derivatives
  80. Weak nonlinear analysis of nanofluid convection with g-jitter using the Ginzburg--Landau model
  81. Strip waveguides in Yb3+-doped silicate glass formed by combination of He+ ion implantation and precise ultrashort pulse laser ablation
  82. Best selected forecasting models for COVID-19 pandemic
  83. Research on attenuation motion test at oblique incidence based on double-N six-light-screen system
  84. Review Articles
  85. Progress in epitaxial growth of stanene
  86. Review and validation of photovoltaic solar simulation tools/software based on case study
  87. Brief Report
  88. The Debye–Scherrer technique – rapid detection for applications
  89. Rapid Communication
  90. Radial oscillations of an electron in a Coulomb attracting field
  91. Special Issue on Novel Numerical and Analytical Techniques for Fractional Nonlinear Schrodinger Type - Part II
  92. The exact solutions of the stochastic fractional-space Allen–Cahn equation
  93. Propagation of some new traveling wave patterns of the double dispersive equation
  94. A new modified technique to study the dynamics of fractional hyperbolic-telegraph equations
  95. An orthotropic thermo-viscoelastic infinite medium with a cylindrical cavity of temperature dependent properties via MGT thermoelasticity
  96. Modeling of hepatitis B epidemic model with fractional operator
  97. Special Issue on Transport phenomena and thermal analysis in micro/nano-scale structure surfaces - Part III
  98. Investigation of effective thermal conductivity of SiC foam ceramics with various pore densities
  99. Nonlocal magneto-thermoelastic infinite half-space due to a periodically varying heat flow under Caputo–Fabrizio fractional derivative heat equation
  100. The flow and heat transfer characteristics of DPF porous media with different structures based on LBM
  101. Homotopy analysis method with application to thin-film flow of couple stress fluid through a vertical cylinder
  102. Special Issue on Advanced Topics on the Modelling and Assessment of Complicated Physical Phenomena - Part II
  103. Asymptotic analysis of hepatitis B epidemic model using Caputo Fabrizio fractional operator
  104. Influence of chemical reaction on MHD Newtonian fluid flow on vertical plate in porous medium in conjunction with thermal radiation
  105. Structure of analytical ion-acoustic solitary wave solutions for the dynamical system of nonlinear wave propagation
  106. Evaluation of ESBL resistance dynamics in Escherichia coli isolates by mathematical modeling
  107. On theoretical analysis of nonlinear fractional order partial Benney equations under nonsingular kernel
  108. The solutions of nonlinear fractional partial differential equations by using a novel technique
  109. Modelling and graphing the Wi-Fi wave field using the shape function
  110. Generalized invexity and duality in multiobjective variational problems involving non-singular fractional derivative
  111. Impact of the convergent geometric profile on boundary layer separation in the supersonic over-expanded nozzle
  112. Variable stepsize construction of a two-step optimized hybrid block method with relative stability
  113. Thermal transport with nanoparticles of fractional Oldroyd-B fluid under the effects of magnetic field, radiations, and viscous dissipation: Entropy generation; via finite difference method
  114. Special Issue on Advanced Energy Materials - Part I
  115. Voltage regulation and power-saving method of asynchronous motor based on fuzzy control theory
  116. The structure design of mobile charging piles
  117. Analysis and modeling of pitaya slices in a heat pump drying system
  118. Design of pulse laser high-precision ranging algorithm under low signal-to-noise ratio
  119. Special Issue on Geological Modeling and Geospatial Data Analysis
  120. Determination of luminescent characteristics of organometallic complex in land and coal mining
  121. InSAR terrain mapping error sources based on satellite interferometry
Sign up now to receive a 20% welcome discount
Institutional Access
How does access work?
Have an idea on how to improve our website?
Please write us.
© 2025 De Gruyter Brill
Downloaded on 12.9.2025 from https://www.degruyterbrill.com/document/doi/10.1515/phys-2022-0022/html
Scroll to top button