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7 results on '"Sathian, Vilippalil"'

1. Development of Dy3+ doped lithium magnesium borate glass system for thermoluminescence based neutron dosimetry applications.

Author

Sen, Meghnath, Shukla, Rakesh, Mishra, Raman K., Pathak, Nimai, Sathian, Vilippalil, and Chaudhury, Probal

Subjects
THERMOLUMINESCENCE dosimetry, BORATE glass, OXIDATION states, THERMOLUMINESCENCE, NEUTRONS, THERMAL neutrons
Abstract

The manuscript reports the synthesis of Dy3+ incorporated lithium magnesium borate glass by melt quenching technique. FTIR study revealed the presence of both BO3 as well as tetrahedral BO4 units through their characteristic frequencies. Photoluminescence (PL) study of unirradiated samples confirmed the presence of Dy dopant in the '+3' oxidation states from the characteristic emissions at 482, 578, 666 and 716 nm corresponding to 4F9/26H15/2, 4F9/26H13/2 and 4F9/26H11/2, 4F9/26H9/2 transitions, respectively. Thermal neutron and gamma irradiated PL emission and lifetime characteristics were discussed in details based on the different defect centers. Thermal neutron irradiated TL study showed that the material has a broad and single dosimetry glow peak at about 450 K which showed high fading due to low temperature peak. TL based neutron sensitivity of LMB: Dy3+ was found to be about 37.4 times less than that of standard TLD-100 (LiF: Mg, Ti) powder. The net TL response from about 3 to 83 mSv of neutron dose was found to be linear (Adj. R2 = 0.9994) which is one of the most desirable properties for dosimetry applications. In addition, the TL trap parameters were evaluated using both deconvolution of TL glow curve and peak shape method as suggested by Chen which were found to be matching with each other. [ABSTRACT FROM AUTHOR]

Published
2024
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2. Establishment and dissemination of radiological standards in the field of diagnostic radiology in India

Author

Vinatha Sumanth Panyam, Sougata Rakshit, Sanjay Daga Dhole, Bhushankumar Jagnnath Patil, Amaren Prasanna Das, Greeshma Anantharaman Kossery, Sathian Vilippalil, and Probal Chaudhury

Subjects
calibration, diagnostic radiology, free-air ionization chamber, Medical physics. Medical radiology. Nuclear medicine, R895-920
Abstract

Background: The increased use of ionizing radiation for diagnostic purpose has resulted in an increase in the world population dose. Patient dosimetry in X-ray diagnostic radiology is required to establish diagnostic reference levels (DRLs) and to assess the average dose received by organs and tissues. International bodies have recommended DRLs to be based on dosimetric quantities. Aim: To cater to the increased requirement for dosimetry in diagnostic radiology, international guidelines are provided to establish and disseminate traceable calibration for dosimeters used in X-ray diagnostic radiology. X-ray diagnostic beams established are standardized using a diagnostic range free-air ionization chamber (DFAIC) (20-150 kV). Materials and Methods: Characterization of the DFAIC and determination of the correction factors for the air kerma measurements were evaluated experimentally and by theoretical calculations. Results: The paper details the establishment of 18 diagnostic beam qualities using DFAIC along with the associated uncertainties. The overall uncertainty for the air kerma measurements was within ±0.5% at 1 sigma level. Eight diagnostic range air kerma measurements using DFAIC were compared with the medium energy primary standard FAIC (50–300 kV) maintained in the laboratory. Conclusion: The air kerma rates agreed within ±1% and are within the overall standard uncertainty of both the chambers at the time of the comparison. Dissemination to the users in the field of diagnostic radiology in the country has been carried out by calibrating their ionization chambers and solid-state detector-based instruments against the DFAIC. The methodology followed to standardize the beams using DFAIC and calibration of dosimeters is presented in this work.

Published
2021
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3. Development of Dy3+doped lithium magnesium borate glass system for thermoluminescence based neutron dosimetry applications

Author

Sen, Meghnath, Shukla, Rakesh, Mishra, Raman K., Pathak, Nimai, Sathian, Vilippalil, and Chaudhury, Probal

Abstract

The manuscript reports the synthesis of Dy3+incorporated lithium magnesium borate glass by melt quenching technique. FTIR study revealed the presence of both BO3as well as tetrahedral BO4units through their characteristic frequencies. Photoluminescence (PL) study of unirradiated samples confirmed the presence of Dy dopant in the ‘+3’ oxidation states from the characteristic emissions at 482, 578, 666 and 716 nm corresponding to 4F9/2→ 6H15/2, 4F9/2→ 6H13/2and 4F9/2→ 6H11/2, 4F9/2→ 6H9/2transitions, respectively. Thermal neutron and gamma irradiated PL emission and lifetime characteristics were discussed in details based on the different defect centers. Thermal neutron irradiated TL study showed that the material has a broad and single dosimetry glow peak at about 450 K which showed high fading due to low temperature peak. TL based neutron sensitivity of LMB: Dy3+was found to be about 37.4 times less than that of standard TLD-100 (LiF: Mg, Ti) powder. The net TL response from about 3 to 83 mSv of neutron dose was found to be linear (Adj. R2= 0.9994) which is one of the most desirable properties for dosimetry applications. In addition, the TL trap parameters were evaluated using both deconvolution of TL glow curve and peak shape method as suggested by Chen which were found to be matching with each other.

Published
2024
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5. Synthesis, characterization, and thermoluminescence‐based high‐dose neutron and gamma dosimetry study of Al5BO9: Mn, Li nanophosphor.

Author

Sen, Meghnath, Shukla, Rakesh, Pathak, Nimai, Ali, Kawsar, Sathian, Vilippalil, and Tyagi, Avesh K.

Subjects
THERMOLUMINESCENCE, RADIATION dosimetry, FOOD irradiation, THERMAL neutrons, NEUTRONS, GAMMA rays, EXCITATION spectrum
Abstract

A near tissue equivalent (Zeff = 10.8) and wide bandgap (Eg = 5.95 eV) Al5BO9: Mn, Li nanophosphor was synthesized by facile gel‐combustion (GC) method, and structural characterizations were performed by XRD, infra‐red, transmission electron microscopy, energy‐dispersive spectra, diffuse reflectance UV–visible spectra, and PL studies. Thermoluminescence (TL) study of Al5BO9: Mn, Li revealed the dosimetry glow peak at 542 K, which was absent in undoped Al5BO9 indicating the importance of Mn dopant. The highest TL response was obtained for the lowest studied dopant concentration (0.1 mol% Mn) that was attributed to the concentration quenching phenomenon. The material is highly reusable with low fading (<10%) up to 110 days. TL response for both thermal neutron and gamma radiations showed excellent linearity within 5 × 109–3 × 1011 n/cm2 and 30–5000 Gy, respectively. These studies suggested promising potential of Al5BO9: Mn, Li nanophosphor in clinical neutron dosimetry and food irradiation dosimetry applications. Based on the variation of calcination temperature, strategy toward dual application, namely, radiation dosimeter and red‐light emitting phosphor of the material was established. For a better understanding of the TL process, various kinetic parameters like activation energy (E), order of kinetics (b), and frequency factor (s) were evaluated using different methodologies, and the results were found to be in good agreement. [ABSTRACT FROM AUTHOR]

Published
2022
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6. Establishment and Dissemination of Radiological Standards in the Field of Diagnostic Radiology in India

Author

Vinatha Sumanth Panyam, Sougata Rakshit, Sanjay Daga Dhole, Bhushankumar Jagnnath Patil, Amaren Prasanna Das, Greeshma Anantharaman Kossery, Sathian Vilippalil, and Probal Chaudhury

Subjects
Medical physics. Medical radiology. Nuclear medicine, free-air ionization chamber, Calibration, R895-920, diagnostic radiology, Original Article
Abstract

Background: The increased use of ionizing radiation for diagnostic purpose has resulted in an increase in the world population dose. Patient dosimetry in X-ray diagnostic radiology is required to establish diagnostic reference levels (DRLs) and to assess the average dose received by organs and tissues. International bodies have recommended DRLs to be based on dosimetric quantities. Aim: To cater to the increased requirement for dosimetry in diagnostic radiology, international guidelines are provided to establish and disseminate traceable calibration for dosimeters used in X-ray diagnostic radiology. X-ray diagnostic beams established are standardized using a diagnostic range free-air ionization chamber (DFAIC) (20-150 kV). Materials and Methods: Characterization of the DFAIC and determination of the correction factors for the air kerma measurements were evaluated experimentally and by theoretical calculations. Results: The paper details the establishment of 18 diagnostic beam qualities using DFAIC along with the associated uncertainties. The overall uncertainty for the air kerma measurements was within ±0.5% at 1 sigma level. Eight diagnostic range air kerma measurements using DFAIC were compared with the medium energy primary standard FAIC (50–300 kV) maintained in the laboratory. Conclusion: The air kerma rates agreed within ±1% and are within the overall standard uncertainty of both the chambers at the time of the comparison. Dissemination to the users in the field of diagnostic radiology in the country has been carried out by calibrating their ionization chambers and solid-state detector-based instruments against the DFAIC. The methodology followed to standardize the beams using DFAIC and calibration of dosimeters is presented in this work.

Published
2020

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