Geant4 Simulation of the Effect of Different Composites on Polyimide Photon and Neutron Shielding Properties

Akhdar, Hanan; Alotaibi, Rawan

doi:10.3390/polym15081973

Cited by 4 publications

(3 citation statements)

References 33 publications

(48 reference statements)

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“…Polyimide (PI) is a high-performance polymer matrix that has been developed since 1950s, and it has excellent low-temperature resistance [ 1 ], high-temperature resistance [ 2 ], radiation resistance [ 3 ], and excellent self-lubricating properties [ 4 ]; as a result, it is widely used in the aerospace industry [ 5 ], triboelectric nanogenerators [ 6 ], and radiation-shielding materials [ 7 ]. However, the coefficient of friction and wear rate of pure PI are relatively high, which limits its application in extreme environments [ 8 ].…”

Section: Introductionmentioning

confidence: 99%

Tribological Properties of Polyimide Composites Modified with Diamondoid Metal–Organic Frameworks

Yu,

Pei,

Pei

et al. 2024

Polymers

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In this work, diamondoid metal-organic frameworks (MOFs) were efficiently prepared by sonochemical synthesis and grown on polyimide (PI), aiming to improve the anti-wear performance of the PI matrix. By introducing MOFs into the PI matrix, the free movement of PI molecular chains were restricted, and its hardness and elastic modulus were improved. It was found that the wear rate of the 3 wt.% MOFs/PI composites was reduced by 72.6% compared to pure PI at a load of 4 N after tribological testing by using a ball-on-disk tribometer. This can be attributed to the excellent load-bearing and shear resistance of the fourfold-interpenetrated diamondoid networks, in which the transition metal elements can favor the formation of transfer films. It is worth noting that the 3 wt.% MOFs/PI composites still exhibited great tribological properties under high loads or high speeds. The findings of the present study indicate that diamondoid metal-organic frameworks can be used as efficient modifiers to enhance the tribological properties of PI.

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Section: Introductionmentioning

confidence: 99%

Tribological Properties of Polyimide Composites Modified with Diamondoid Metal–Organic Frameworks

Yu,

Pei,

Pei

et al. 2024

Polymers

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“…However, the development of metal oxide PLA composites has allowed for a greater advantage in this area [ 17 , 18 ]. Computer simulation work using the Geant4 Monte Carlo code has evaluated the potential capacity that PLA compounds doped with oxides of Mg, Fe, Zn, and Ti [ 17 ] and polyimide compounds doped with Zn, Ti, Ag, and Au [ 19 ] would have for photon and neutrons shielding in a wide energy range (10–2000 keV). Additionally, polymers doped with Ag nanoparticles have also been experimentally analyzed for their effectiveness in shielding against 662 keV gamma rays [ 20 ].…”

Section: Introductionmentioning

confidence: 99%

“…Modern radiotherapy uses electron linear accelerators (6)(7)(8)(9)(10)(11)(12)(13)(14)(15)(16)(17)(18), which produce photons with MeV energies, with the capacity to penetrate matter significantly more than the keV energies assessed thus far [24]. For a medium such as PLA or Polyethylene, the linear attenuation coefficient for the 20-100 keV range is 0.7773-0.1996 cm −1 [19,24] whereas for the same materials at energies in the 1-6 MeV range the linear attenuation coefficients are in average 8.4 times lower (0.0838-0.0324 cm −1 ) [19,24], which will result in an attenuation 3-4 orders of magnitude lower for 1-6 MeV photons. This suggests that the production of any type of radiotherapy accessory by MEX would require polymeric compounds doped with high Z and high-density metals (such as W or Pb with linear attenuation coefficients of 1.2740-0.8104 cm −1 and 0.8054-0.4979 cm −1 respectively for 1-6 MeV [24]) in concentrations exceeding 90% to achieve attenuation of the radiation beam to 1/7 of its value in reasonable thickness dimensions.…”

Section: Introductionmentioning

confidence: 99%

Characterization of Radiation Shielding Capabilities of High Concentration PLA-W Composite for 3D Printing of Radiation Therapy Collimators

Velásquez,

Fuentealba,

Santibáñez

2024

Polymers

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This work evaluates the radiation shielding capabilities of the PLA-W composite for MV energy photons emitted by a linear accelerator and the feasibility of manufacturing a clinically-used collimator grid in spatially fractionated radiotherapy (SFRT) using the material extrusion (MEX) 3D printing technique. The PLA-W filament used has a W concentration of 93% w/w and a green density of 7.51 g/cm3, characteristics that make it suitable for this purpose. Relevant parameters such as the density and homogeneity distribution of W in the manufactured samples determine the mass attenuation coefficient, directly affecting the radiation shielding capacities, so different printing parameters were evaluated, such as layer height, deposition speed, nozzle temperature, and infill, to improve the protection performance of the samples. Additionally, physical and mechanical tests were conducted to ensure structural stability and spatial variability over time, which are critical to ensure precise spatial modulation of radiation. Finally, a complete collimator grid measuring 9.3 × 9.3 × 7.1 cm3 (consisting of 39 conical collimators with a diameter of 0.92 cm and center-to-center spacing of 1.42 cm) was manufactured and experimentally evaluated on a clinical linear accelerator to measure the radiation shielding and dosimetric parameters such as mass attenuation coefficient, half-value layer (HVL), dosimetric collimator field size, and inter-collimator transmission using radiochromic films and 2D diode array detectors, obtaining values of 0.04692 cm2/g, 2.138 cm, 1.40 cm, and 15.6%, respectively, for the parameters in the study. This shows the viability of constructing a clinically-used collimator grid through 3D printing.

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Multiscale Design and Fabrication of Neutron Shielding Fiber-Reinforced Composites Via Boron-Based Polymer and Layer-by-Layer Self-Assembly of Go/B4c on Carbon Fiber Surface

Gu,

Liu,

yang

et al. 2024

Preprint

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Geant4 Simulation of the Effect of Different Composites on Polyimide Photon and Neutron Shielding Properties

Cited by 4 publications

References 33 publications

Tribological Properties of Polyimide Composites Modified with Diamondoid Metal–Organic Frameworks

Tribological Properties of Polyimide Composites Modified with Diamondoid Metal–Organic Frameworks

Characterization of Radiation Shielding Capabilities of High Concentration PLA-W Composite for 3D Printing of Radiation Therapy Collimators

Multiscale Design and Fabrication of Neutron Shielding Fiber-Reinforced Composites Via Boron-Based Polymer and Layer-by-Layer Self-Assembly of Go/B4c on Carbon Fiber Surface

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