تابش گاما در سنتز Ag-NPs پیوندیافته به سطوح پلی‌پروپیلنی و اصلاح عملکرد سیستم آب بدون یون در الگودهی نیم‌رسانا

غراب, فرزانه; اسحاقی, زرین; شیخ, نسرین; اخوان, اعظم

doi:10.24200/nst.2021.1184

نوع مقاله : مقاله پژوهشی

نویسندگان

¹ پژوهشکده فوتونیک و فناوری‌های کوانتومی، پژوهشگاه علوم و فنون هسته‌ای، سازمان انرژی اتمی ایران، صندوق‌پستی 13-14399511، تهران- ایران

² گروه شیمی تجزیه، دانشکده شیمی، دانشگاه پیام‌نور، صندوق‌پستی 9189896311، مشهد- ایران

³ پژوهشکده کاربرد پرتوها، پژوهشگاه علوم و فنون هسته‌ای، سازمان انرژی اتمی ایران، صندوق‌پستی 3486-11365، تهران- ایران

https://doi.org/10.24200/nst.2021.1184

چکیده

کاربرد تابش گاما به‌عنوان عامل سنتز پرتوی نانوذرات نقره و پیوند همزمان آن ذرات به سطوح پلی‌پروپیلنی در اصلاح عملکرد سیستم تهیه آب بدون یون، پروژه تجربی نوینی است. در این پروژه، استفاده از تأثیر پرتو گاما بر روی سطح نوع خاصی از فیلتر، موجب احیای یون‌های نقره و اصلاح سطح فیلتر به‌طور همزمان گردید. سپس، اثر فیلتر اصلاح شده بر عملکرد سیستم‌های تهیه آب بدون یون، که به‌طور مستقیم و غیر‌مستقیم با فن‌آوری‌های کوانتومی وعلوم هسته‌ای ارتباط دارند، از طریق الگودهی سطح نیم‌رسانای ایندیم فسفاید بررسی شد. تعیین میزان دز تابش گاما و بررسی شرایط احیای نانوذرات نقره، پس از گذر از مرحله بهینه‌سازی، صورت گرفت. بر این اساس، از اطلاعات میکروسکوپ الکترونی روبشی، طیف‌سنجی پراکندگی انرژی پرتو ایکس، طیف‌سنجی جذبی فرابنفش- مریی، طیف‌های بازتاب کل تضعیف شده و آزمون‌های شمارش باکتری‌ها در سطوح آغشته به آگار استفاده شد. سپس مشخص گردید که نتیجه مطلوب اصلاح سطح فیلتر، به‌دلیل ایجاد رزونانس پلاسمون سطحی در محلول کلوییدی نانو ذرات نقره می‌باشد که به هنگام سنتز با تابش گاما به وجود می‌آید.

کلیدواژه‌ها

20.1001.1.17351871.1400.42.1.6.2

عنوان مقاله [English]

Gamma Irradiation in Grafted Ag-NPs Synthesis to PP Surfaces and DI Water System Modification in Semiconductor Patterning

نویسندگان [English]

F. Ghorab ¹ ²
Z. Eshaghi ²
N. Sheikh ³
A. Akhavan ³

¹ The Photonic and Quantum Technology Research School, Nuclear Science and Technology Research Institute, AEOI, P.O.BOX: 14395-836, Tehran, Iran

² The Photonic and Quantum Technology Research School, Nuclear Science and Technology Research Institute, AEOI, P.O.BOX: 14395-836, Tehran, Iran

³ Radiation Applications Research School, Nuclear Science and Technology Research Institute, AEOI, P.O.BOX: 14395-836, Tehran, Iran

چکیده [English]

The application of gamma irradiation as a factor to graft the synthesized silver nanoparticles to the polypropylene surface and modify the de-ionized (DI) water supply system is a new experimental project. In this study, using the effect of gamma irradiation on the surface of a certain type of filter, reduces silver ions and modifies the filter surface simultaneously. Then, the effect of the modified filter on the performance of DI water supply systems, which are directly and indirectly related to quantum technologies and nuclear science, was investigated by modeling on the surface of indium phosphide (InP) semiconductor. The dose of gamma irradiation and the reduction conditions of silver nanoparticles were determined after passing the optimization stage. So, scanning electron microscopy (SEM), energy-dispersive X-ray spectroscopy (EDX), ultraviolet-visible absorption spectroscopy (UV-Vis), attenuated total reflection (ATR) and bacterial counting tests by plate count agar (PCA) were used. Then it was found that the desired result of filter surface modification is due to the formation of surface plasmon resonance in the colloidal solution of silver nanoparticles which is produced during gamma irradiation synthesis.

کلیدواژه‌ها [English]

Gamma irradiation
Filter surface modification
Silver nanoparticles synthesis
Semiconductor surface patterning

مراجع

1. K. Nicolai, et al, Polarization-state-resolved high-harmonic spectroscopy of solids, Nature communications, 10 (1), 1319 (2019).

2. P. Peng, C. Marceau, D.M. Villeneuve, Attosecond imaging of molecules using high harmonic spectroscopy, Nature Reviews Physics, 1(2), 144 (2019).

3. F. Lei, et al, Correlations in high-harmonic generation of matter-wave jets revealed by pattern recognition, Science, 363, 6426, 521-524 (2019).

4. J. Shicheng, et al, Role of the transition dipole amplitude and phase on the generation of odd and even high-order harmonics in crystals, Physical Review Letters, 120(5), 253201 (2018).

5. L. Hanzhe, et al, Enhanced high-harmonic generation from an all-dielectric metasurface, Nature Physics, 14(10), 1006 (2018).

6. T.J. Hammond, et al, Integrating solids and gases for attosecond pulse generation, Nature Photonics, 11(9), 594 (2017).

7. C. Henning, et al, High-harmonic generation at 250 MHz with photon energies exceeding 100 eV, Optica, 3(4), 366-369 (2016).

8. M. Monfared, E. Irani, R. Sadighi-Bonab, Enhancing high harmonic generation by the global optimization of two-color chirped laser field, Physical Chemistry Chemical Physics, (2019).

9. P. Tenio, et al, Bright coherent ultrahigh harmonics in the keV x-ray regime from mid-infrared femtosecond lasers, Science, 336(6086), 1287-1291 (2012).

10. K. Zhao, et al, Tailoring a 67 attosecond pulse through advantageous phase-mismatch, Optics Letters, 37(18), 3891-3893 (2012).

11. G. Vampa, et al, Plasmon-enhanced high-harmonic generation from silicon, Nature Physics, 13(7), 659 (2017).

12. M. Toru, et al, Accurate retrieval of structural information from laser-induced photoelectron and high-order harmonic spectra by few-cycle laser pulses, Physical Review Letters, 100(1), 013903 (2008).

13. J. Itatani, et al, Tomographic imaging of molecular orbitals, Nature, 432 (7019), 867 (2004).

14. P.B. Corkum, Plasma perspective on strong field multiphoton ionization, Physical Review Letters, 71(13), 1994 (1993).

15. M. Lewenstein, et al, Theory of high-harmonic generation by low-frequency laser fields, Physical Review A, 49(3), 2117 (1994).

16. M. Monfared, E. Irani, R. Sadighi-Bonabi, Controlling the multi-electron dynamics in the high harmonic spectrum from N₂O molecule using TDDFT, The Journal of Chemical Physics, 148(23), 234303 (2018).

17. Parr, Robert G. Density functional theory of atoms and molecules, Horizons of Quantum Chemistry, Springer, Dordrecht, 5-15 (1980).

18. Hartwigsen, C., Sephen Gœdecker, Jürg Hutter, Relativistic separable dual-space Gaussian pseudopotentials from H to Rn, Physical Review B, 58.7, 3641 (1998).

19. Perdew, John P., Alex Zunger, Self-interaction correction to density-functional approximations for many-electron systems, Physical Review B, 23.10, 5048 (1981).

20. Andrade, Xavier, et al., Real-space grids and the Octopus code as tools for the development of new simulation approaches for electronic systems, Physical Chemistry Chemical Physics, 17(47), 31371-31396 (2015).

21. Lewenstein, Maciej, et al., Theory of high-harmonic generation by low-frequency laser fields, Physical Review A, 49.3, 2117 (1994).

22. Antoine, Philippe, Bernard Piraux, Alfred Maquet, Time profile of harmonics generated by a single atom in a strong electromagnetic field, Physical Review A, 51.3, R1750 (1995).

23. Feng, Liqiang, Hang Liu, Attosecond-resolution molecular high-order harmonic emission and isolated attosecond pulse generation from H2+, Optics Communications, 389, 144-149 (2017).

24. Wörner, Hans Jakob, et al, Observation of electronic structure minima in high-harmonic generation, Physical Review Letters, 102.10, 103901 (2009).

25. Rupenyan, Alisa, et al, High-harmonic spectroscopy of isoelectronic molecules: Wavelength scaling of electronic-structure and multielectron effects, Physical Review A, 87.3, 033409 (2013).

26. Bian, Xue-Bin, André D. Bandrauk, Multichannel molecular high-order harmonic generation from asymmetric diatomic molecules, Physical Review Letters, 105.9, 093903 (2010).

مجله علوم و فنون هسته ای

تابش گاما در سنتز Ag-NPs پیوندیافته به سطوح پلی‌پروپیلنی و اصلاح عملکرد سیستم آب بدون یون در الگودهی نیم‌رسانا

مراجع

مراجع

1. K. Nicolai, et al, Polarization-state-resolved high-harmonic spectroscopy of solids, Nature communications, 10 (1), 1319 (2019).

2. P. Peng, C. Marceau, D.M. Villeneuve, Attosecond imaging of molecules using high harmonic spectroscopy, Nature Reviews Physics, 1(2), 144 (2019).

3. F. Lei, et al, Correlations in high-harmonic generation of matter-wave jets revealed by pattern recognition, Science, 363, 6426, 521-524 (2019).

4. J. Shicheng, et al, Role of the transition dipole amplitude and phase on the generation of odd and even high-order harmonics in crystals, Physical Review Letters, 120(5), 253201 (2018).

5. L. Hanzhe, et al, Enhanced high-harmonic generation from an all-dielectric metasurface, Nature Physics, 14(10), 1006 (2018).

6. T.J. Hammond, et al, Integrating solids and gases for attosecond pulse generation, Nature Photonics, 11(9), 594 (2017).

7. C. Henning, et al, High-harmonic generation at 250 MHz with photon energies exceeding 100 eV, Optica, 3(4), 366-369 (2016).

8. M. Monfared, E. Irani, R. Sadighi-Bonab, Enhancing high harmonic generation by the global optimization of two-color chirped laser field, Physical Chemistry Chemical Physics, (2019).

9. P. Tenio, et al, Bright coherent ultrahigh harmonics in the keV x-ray regime from mid-infrared femtosecond lasers, Science, 336(6086), 1287-1291 (2012).

10. K. Zhao, et al, Tailoring a 67 attosecond pulse through advantageous phase-mismatch, Optics Letters, 37(18), 3891-3893 (2012).

11. G. Vampa, et al, Plasmon-enhanced high-harmonic generation from silicon, Nature Physics, 13(7), 659 (2017).

12. M. Toru, et al, Accurate retrieval of structural information from laser-induced photoelectron and high-order harmonic spectra by few-cycle laser pulses, Physical Review Letters, 100(1), 013903 (2008).

13. J. Itatani, et al, Tomographic imaging of molecular orbitals, Nature, 432 (7019), 867 (2004).

14. P.B. Corkum, Plasma perspective on strong field multiphoton ionization, Physical Review Letters, 71(13), 1994 (1993).

15. M. Lewenstein, et al, Theory of high-harmonic generation by low-frequency laser fields, Physical Review A, 49(3), 2117 (1994).

16. M. Monfared, E. Irani, R. Sadighi-Bonabi, Controlling the multi-electron dynamics in the high harmonic spectrum from N₂O molecule using TDDFT, The Journal of Chemical Physics, 148(23), 234303 (2018).

17. Parr, Robert G. Density functional theory of atoms and molecules, Horizons of Quantum Chemistry, Springer, Dordrecht, 5-15 (1980).

18. Hartwigsen, C., Sephen Gœdecker, Jürg Hutter, Relativistic separable dual-space Gaussian pseudopotentials from H to Rn, Physical Review B, 58.7, 3641 (1998).

19. Perdew, John P., Alex Zunger, Self-interaction correction to density-functional approximations for many-electron systems, Physical Review B, 23.10, 5048 (1981).

20. Andrade, Xavier, et al., Real-space grids and the Octopus code as tools for the development of new simulation approaches for electronic systems, Physical Chemistry Chemical Physics, 17(47), 31371-31396 (2015).

21. Lewenstein, Maciej, et al., Theory of high-harmonic generation by low-frequency laser fields, Physical Review A, 49.3, 2117 (1994).

22. Antoine, Philippe, Bernard Piraux, Alfred Maquet, Time profile of harmonics generated by a single atom in a strong electromagnetic field, Physical Review A, 51.3, R1750 (1995).

23. Feng, Liqiang, Hang Liu, Attosecond-resolution molecular high-order harmonic emission and isolated attosecond pulse generation from H2+, Optics Communications, 389, 144-149 (2017).

24. Wörner, Hans Jakob, et al, Observation of electronic structure minima in high-harmonic generation, Physical Review Letters, 102.10, 103901 (2009).

25. Rupenyan, Alisa, et al, High-harmonic spectroscopy of isoelectronic molecules: Wavelength scaling of electronic-structure and multielectron effects, Physical Review A, 87.3, 033409 (2013).

26. Bian, Xue-Bin, André D. Bandrauk, Multichannel molecular high-order harmonic generation from asymmetric diatomic molecules, Physical Review Letters, 105.9, 093903 (2010).

دوره 42، شماره 1 - شماره پیاپی 95
اردیبهشت 1400
صفحه 48-56

تابش گاما در سنتز Ag-NPs پیوندیافته به سطوح پلی‌پروپیلنی و اصلاح عملکرد سیستم آب بدون یون در الگودهی نیم‌رسانا

مراجع

مراجع

1. K. Nicolai, et al, Polarization-state-resolved high-harmonic spectroscopy of solids, Nature communications, 10 (1), 1319 (2019).

2. P. Peng, C. Marceau, D.M. Villeneuve, Attosecond imaging of molecules using high harmonic spectroscopy, Nature Reviews Physics, 1(2), 144 (2019).

3. F. Lei, et al, Correlations in high-harmonic generation of matter-wave jets revealed by pattern recognition, Science, 363, 6426, 521-524 (2019).

4. J. Shicheng, et al, Role of the transition dipole amplitude and phase on the generation of odd and even high-order harmonics in crystals, Physical Review Letters, 120(5), 253201 (2018).

5. L. Hanzhe, et al, Enhanced high-harmonic generation from an all-dielectric metasurface, Nature Physics, 14(10), 1006 (2018).

6. T.J. Hammond, et al, Integrating solids and gases for attosecond pulse generation, Nature Photonics, 11(9), 594 (2017).

7. C. Henning, et al, High-harmonic generation at 250 MHz with photon energies exceeding 100 eV, Optica, 3(4), 366-369 (2016).

8. M. Monfared, E. Irani, R. Sadighi-Bonab, Enhancing high harmonic generation by the global optimization of two-color chirped laser field, Physical Chemistry Chemical Physics, (2019).

9. P. Tenio, et al, Bright coherent ultrahigh harmonics in the keV x-ray regime from mid-infrared femtosecond lasers, Science, 336(6086), 1287-1291 (2012).

10. K. Zhao, et al, Tailoring a 67 attosecond pulse through advantageous phase-mismatch, Optics Letters, 37(18), 3891-3893 (2012).

11. G. Vampa, et al, Plasmon-enhanced high-harmonic generation from silicon, Nature Physics, 13(7), 659 (2017).

12. M. Toru, et al, Accurate retrieval of structural information from laser-induced photoelectron and high-order harmonic spectra by few-cycle laser pulses, Physical Review Letters, 100(1), 013903 (2008).

13. J. Itatani, et al, Tomographic imaging of molecular orbitals, Nature, 432 (7019), 867 (2004).

14. P.B. Corkum, Plasma perspective on strong field multiphoton ionization, Physical Review Letters, 71(13), 1994 (1993).

15. M. Lewenstein, et al, Theory of high-harmonic generation by low-frequency laser fields, Physical Review A, 49(3), 2117 (1994).

16. M. Monfared, E. Irani, R. Sadighi-Bonabi, Controlling the multi-electron dynamics in the high harmonic spectrum from N2O molecule using TDDFT, The Journal of Chemical Physics, 148(23), 234303 (2018).

17. Parr, Robert G. Density functional theory of atoms and molecules, Horizons of Quantum Chemistry, Springer, Dordrecht, 5-15 (1980).

18. Hartwigsen, C., Sephen Gœdecker, Jürg Hutter, Relativistic separable dual-space Gaussian pseudopotentials from H to Rn, Physical Review B, 58.7, 3641 (1998).

19. Perdew, John P., Alex Zunger, Self-interaction correction to density-functional approximations for many-electron systems, Physical Review B, 23.10, 5048 (1981).

20. Andrade, Xavier, et al., Real-space grids and the Octopus code as tools for the development of new simulation approaches for electronic systems, Physical Chemistry Chemical Physics, 17(47), 31371-31396 (2015).

21. Lewenstein, Maciej, et al., Theory of high-harmonic generation by low-frequency laser fields, Physical Review A, 49.3, 2117 (1994).

22. Antoine, Philippe, Bernard Piraux, Alfred Maquet, Time profile of harmonics generated by a single atom in a strong electromagnetic field, Physical Review A, 51.3, R1750 (1995).

23. Feng, Liqiang, Hang Liu, Attosecond-resolution molecular high-order harmonic emission and isolated attosecond pulse generation from H2+, Optics Communications, 389, 144-149 (2017).

24. Wörner, Hans Jakob, et al, Observation of electronic structure minima in high-harmonic generation, Physical Review Letters, 102.10, 103901 (2009).

25. Rupenyan, Alisa, et al, High-harmonic spectroscopy of isoelectronic molecules: Wavelength scaling of electronic-structure and multielectron effects, Physical Review A, 87.3, 033409 (2013).

26. Bian, Xue-Bin, André D. Bandrauk, Multichannel molecular high-order harmonic generation from asymmetric diatomic molecules, Physical Review Letters, 105.9, 093903 (2010).

دوره 42، شماره 1 - شماره پیاپی 95اردیبهشت 1400صفحه 48-56

16. M. Monfared, E. Irani, R. Sadighi-Bonabi, Controlling the multi-electron dynamics in the high harmonic spectrum from N₂O molecule using TDDFT, The Journal of Chemical Physics, 148(23), 234303 (2018).

دوره 42، شماره 1 - شماره پیاپی 95
اردیبهشت 1400
صفحه 48-56