Year 2021,
Volume: 34 Issue: 2, 550 - 560, 01.06.2021
Husam Sabeeh Al-arab
,
Mahasin Al-kadhemy
,
Asrar Abdulmunem Saeed
References
- [1] Chubinidze, K., Partsvania, B., Devadze, L., Zurabishvili, T., Sepashvili, N., Petriashvili, G., Chubinidze M., "Gold Nanoparticle Conjugated Organic Dye Nanocomposite Based Photostimulated Luminescent Enhancement and Its Application in Nanomedicine", American Journal of Nano Research and Applications, Special Issue: Nanotechnologies, 5 (3): 42-47, (2017).
- [2] Wang, H. Y., Zhang, H., Chen, S., Liu, Y., "Fluorescein-Inspired Near-Infrared Chemodosimeter for Luminescence Bioimaging", Current Medicinal Chemistry, 24: 1–12 (2017).
- [3] Amador-Patarroyo, M. J., Lin, T., Meshi, A., Dans, K. C., Chen, K., Borooah, S., Molano-Gonzalez, N., Díaz-Rojas, A. J., Freeman, W. R., "Identifying the factors for improving quality of oral fluorescein angiography", British Journal of Ophthalmology, 2019-314187 (2019).
- [4] Ge, L., Li, Q., Wang, M., Ouyang, J., Li, X., Xing, M. M. Q., “Nanosilver particles in medical applications: Synthesis, performance, and toxicity,” International Journal of Nanomedicine, 9, (1): 2399–2407, (2014).
- [5] Hoa, D. Q., Lien, N. T. H., Duong, V. T. T., Duong, V., An, N. T. M., "Optical Features of Spherical Gold Nanoparticle-Doped Solid-State Dye Laser Medium", Journal of Electronic Materials, 45: 2484–2489, (2016).
- [6] Al-Arab, H. S., Al-Kadhemy, M. F. H. and Saeed, A. A., "A Random Laser Production Using Fluorescein Dye Doped TiO2 Nanoparticles", Iraqi Journal of Science, 60: 1000-1005, (2019).
- [7] Al-Kadhemy, M. F. H., Al-Zuky, A. and Al-Sharuee, I. F., "Theoretical Model to Study the Effect of Concentration and Impurities on the Fluorescence Spectrum of Fluorescein Solution in Ethanol using Fourier Series 3× 2", International Journal of Materials Physics, 2: 75–86, (2011).
- [8] Zeinidenov, A. K., Ibrayev, N. K. and Gladkova, V. K., "Effect of silver nanoparticles on luminescent and generation properties of rhodamine 6G in aqueous alcohol solutions", Russian Journal of Physical Chemistry A, 90: 2440–2443, (2016).
- [9] Barzan, M., Hajiesmaeilbaigi, F., "Effect of gold nanoparticles on the optical properties of Rhodamine 6G", European Physical Journal D, 70 (5): 121, (2016).
- [10] Myers, D., Kitchen, N., Sudduth, K., Miles, R. J., Sadler, E., Grunwald, S., "Peak functions for modeling high-resolution soil profile data", Geoderma, 166 (1): 74-83, (2011).
- [11] Rotscholl, I., Trampert, K., Krüger, U., Schmidt, F., "Spectral near field data of LED systems for optical simulations", Proc. SPIE 11144, Photonics and Education in Measurement Science, 111440P, (2019).
- [12] Al-Arab, H. S., "Effects of Adding Nanoparticles to Laser Dyes on Photophysical Processes and Estimating Theoretical Models for Some of These Processes", Ph.D. Thesis, Mustansiriyah University, Baghdad, 28, (2019).
Estimation of Theoretical Models of Photophysical Processes for Fluorescein Laser Dye with Ag Nanoparticles
Year 2021,
Volume: 34 Issue: 2, 550 - 560, 01.06.2021
Husam Sabeeh Al-arab
,
Mahasin Al-kadhemy
,
Asrar Abdulmunem Saeed
Abstract
In this study, a novel theoretical method for the absorption and fluorescence spectral estimations has been presented. These estimations have been based on experimental measurements of absorption and fluorescence spectra for the solutions of Fluorescein laser dye with Silver (Ag) nanoparticles in distilled water. The used concentration was (1x10-5 M) for Fluorescein dye, while the mass amounts were (0.003g, 0.005g, 0.0065g, 0.008g and 0.0085g) for Silver nanoparticles. A spectral absorption enhancement was detected in the case of increased Silver nanoparticle masses, which specify that the doped Fluorescein dye with Ag nanoparticles has an important effect on the dye absorption spectra. On the other hand, each fluorescence emission spectrum for the dye has quenched as Ag nanoparticle's mass amounts have increased. The related amounts of mass increase as a consequence of Förster resonance energy transfer (FRET). The novel approach of theoretical estimations has been based on curve fitting using Logistic Power Peak (LPP) function to estimate theoretical models for the absorption and fluorescence spectra of these samples. These rated models have excellent matching profiles with the experimental profiles so that the estimated models can replace the experimental measurements.
References
- [1] Chubinidze, K., Partsvania, B., Devadze, L., Zurabishvili, T., Sepashvili, N., Petriashvili, G., Chubinidze M., "Gold Nanoparticle Conjugated Organic Dye Nanocomposite Based Photostimulated Luminescent Enhancement and Its Application in Nanomedicine", American Journal of Nano Research and Applications, Special Issue: Nanotechnologies, 5 (3): 42-47, (2017).
- [2] Wang, H. Y., Zhang, H., Chen, S., Liu, Y., "Fluorescein-Inspired Near-Infrared Chemodosimeter for Luminescence Bioimaging", Current Medicinal Chemistry, 24: 1–12 (2017).
- [3] Amador-Patarroyo, M. J., Lin, T., Meshi, A., Dans, K. C., Chen, K., Borooah, S., Molano-Gonzalez, N., Díaz-Rojas, A. J., Freeman, W. R., "Identifying the factors for improving quality of oral fluorescein angiography", British Journal of Ophthalmology, 2019-314187 (2019).
- [4] Ge, L., Li, Q., Wang, M., Ouyang, J., Li, X., Xing, M. M. Q., “Nanosilver particles in medical applications: Synthesis, performance, and toxicity,” International Journal of Nanomedicine, 9, (1): 2399–2407, (2014).
- [5] Hoa, D. Q., Lien, N. T. H., Duong, V. T. T., Duong, V., An, N. T. M., "Optical Features of Spherical Gold Nanoparticle-Doped Solid-State Dye Laser Medium", Journal of Electronic Materials, 45: 2484–2489, (2016).
- [6] Al-Arab, H. S., Al-Kadhemy, M. F. H. and Saeed, A. A., "A Random Laser Production Using Fluorescein Dye Doped TiO2 Nanoparticles", Iraqi Journal of Science, 60: 1000-1005, (2019).
- [7] Al-Kadhemy, M. F. H., Al-Zuky, A. and Al-Sharuee, I. F., "Theoretical Model to Study the Effect of Concentration and Impurities on the Fluorescence Spectrum of Fluorescein Solution in Ethanol using Fourier Series 3× 2", International Journal of Materials Physics, 2: 75–86, (2011).
- [8] Zeinidenov, A. K., Ibrayev, N. K. and Gladkova, V. K., "Effect of silver nanoparticles on luminescent and generation properties of rhodamine 6G in aqueous alcohol solutions", Russian Journal of Physical Chemistry A, 90: 2440–2443, (2016).
- [9] Barzan, M., Hajiesmaeilbaigi, F., "Effect of gold nanoparticles on the optical properties of Rhodamine 6G", European Physical Journal D, 70 (5): 121, (2016).
- [10] Myers, D., Kitchen, N., Sudduth, K., Miles, R. J., Sadler, E., Grunwald, S., "Peak functions for modeling high-resolution soil profile data", Geoderma, 166 (1): 74-83, (2011).
- [11] Rotscholl, I., Trampert, K., Krüger, U., Schmidt, F., "Spectral near field data of LED systems for optical simulations", Proc. SPIE 11144, Photonics and Education in Measurement Science, 111440P, (2019).
- [12] Al-Arab, H. S., "Effects of Adding Nanoparticles to Laser Dyes on Photophysical Processes and Estimating Theoretical Models for Some of These Processes", Ph.D. Thesis, Mustansiriyah University, Baghdad, 28, (2019).