Radiation shielding performance of high entropy alloys and derived nanomaterials towards nuclear irradiation/electromagnetic interference environments - fundamentals and technicalities

• Autorzy: Kausar Ayesha

Identyfikatory

DOI

10.2478/adms-2025-0011

• Języki publikacji: EN

Abstrakty

EN

Recently, we note, high entropy alloys have attained incalculable research curiosity owing to remarkable elemental combinations, microstructural features, phase structure/stability, and superior physical characters mainly mechanical, thermal, and corrosion resistance under extreme working conditions. Interestingly, these materials have been found capable of sustaining the mechanical and anticorrosion properties at considerably high temperatures. In addition to the energy, engineering, and biomedical fields, high entropy alloys have been frequently explored for radiation protection applications. In nuclear sector, high entropy alloys and nanocomposite alloys exhibited worthy radiation defense towards wide ranging energetic particles including fast neutrons, gamma rays, electrons/ions, and other radionuclides. Consequently, plentiful high entropy alloys and related nanomaterial (nanocarbons, polymers, inorganic) designs have been found promising as functional bulk material/coatings for nuclear radiation as well as electromagnetic interference defiance. Accordingly, the appropriate experimental as well as theoretical approaches have been applied to study the structure, durability, and nuclear shielding effectiveness. In this context, various active mechanisms have been reported, including the micro-level changes, phase transformations, reduced thermal conductivity, and related radiation induced effects. Henceforth, this all-inclusive state-of-the-art overview, we believe, enlightens the significance of high performance high entropy alloys and nanomaterials for technical radiation defense applications against nuclear and electromagnetic interfering irradiations. In addition to radiation shielding parameters, the next generation high entropy alloy shields have been surveyed for synergistic mechanical, thermal, and anticorrosion features desirable against extreme nuclear/fission reactors environments.

Słowa kluczowe

EN

high entropy alloys; nanocomposite; nuclear; electromagnetic; radiation shielding; microstructure

PL

stop o wysokiej entropii; nanokompozyt; nuklearność; elektromagnetyzm; ochrona radiologiczna; mikrostruktura

• Wydawca: Politechnika Gdańska
• Czasopismo: Advances in Materials Science
• Rocznik: 2025
• Tom: Vol. 25, nr 2(84)
• Strony: 73--103
• Opis fizyczny: Bibliogr. 131 poz., rys., tab., wykr.

Twórcy

autor

Kausar Ayesha

• National Center For Physics, Quaid-i-Azam University Campus, Islamabad, Pakistan

Bibliografia

• 1. Yin, K., et al., Prediction of phase stabilities of solid solutions for high entropy alloys. Acta Materialia, 2024. 263: p. 119445.
• 2. Younes, R., et al., Investigation on the influence of tempering on microstructure and wear properties of high alloy chromium cast iron. Advances in Materials Science, 2021. 21(2): p. 65-76.
• 3. Yang, Z., et al., Discontinuous coarsening leads to unchanged tensile properties in high-entropy alloys with different recrystallization volume fractions. International Journal of Plasticity, 2024. 176: p. 103963.
• 4. Ye, W., et al., Recent advances in self-lubricating metal matrix nanocomposites reinforced by carbonous materials: A review. Nano Materials Science, 2024.
• 5. Ye, W., et al., Robust wear performance of graphene-reinforced high entropy alloy composites. Carbon, 2024. 224: p. 119040.
• 6. Peng, Y., et al., Strength-ductility synergy in a novel carbon nanotube-high entropy alloy co-reinforced aluminum matrix composite. Composites Part A: Applied Science and Manufacturing, 2024. 181: p. 108116.
• 7. Ritter, T.G., S. Pappu, and R. Shahbazian‐Yassar, Scalable Synthesis Methods for High‐Entropy Nanoparticles. Advanced Energy and Sustainability Research, 2024: p. 2300297.
• 8. Siengchin, S., A review on lightweight materials for defence applications: A present and future developments. Defence Technology, 2023.
• 9. Searight, W.T., High Temperature Furnace Testing of Structural Materials for Advanced Terrestrial and Space Reactors. 2023: The Pennsylvania State University.
• 10. Liang, Z., et al., Tracking the evolution of niobium cycle in China from 2000 to 2021: A dynamic material flow analysis. Journal of Cleaner Production, 2024. 434: p. 140455.
• 11. El-Emam, R.S., et al., Nuclear and renewables in multipurpose integrated energy systems: A critical review. Renewable and Sustainable Energy Reviews, 2024. 192: p. 114157.
• 12. Hernández-Murillo, C.G., et al., The gamma rays and the shielding, in Advanced Radiation Shielding Materials. 2024, Elsevier. p. 25-44.
• 13. Saeed, A., et al., Glass Materials in Nuclear Technology for Gamma Ray and Neutron Radiation Shielding: a Review. Nonlinear Optics, Quantum Optics: Concepts in Modern Optics, 2021. 53.
• 14. Li, H., et al., Flexible and wearable functional materials for ionizing radiation Protection: A perspective review. Chemical Engineering Journal, 2024: p. 150583.
• 15. Krishna, S.A., et al., A comprehensive review on advances in high entropy alloys: Fabrication and surface modification methods, properties, applications, and future prospects. Journal of Manufacturing Processes, 2024. 109: p. 583-606.
• 16. Al-Ubaidy, S.K. and C. Bouraoui. High-Entropy Alloys: Advantages and Applications in Challenging Environments. in Annales de Chimie Science des Matériaux. 2024.
• 17. Zheng, S., et al., Recent advances in structural design of conductive polymer composites for electromagnetic interference shielding. Polymer Composites, 2024. 45(1): p. 43-76.
• 18. Moschetti, M., et al., A novel strategy for the design of compositionally complex alloys for advanced nuclear applications. Applied Materials Today, 2024. 38: p. 102164.
• 19. Hummel, E.J., M.A. Roxburgh, and H.D. Huisman, An elemental exploration of the metal. Estonian Journal of Archaeology, 2024. 28(1): p. 29-53.
• 20. Miracle, D.B., et al., Exploration and development of high entropy alloys for structural applications. Entropy, 2014. 16(1): p. 494-525.
• 21. Zhang, Y., High entropy materials. 2023: Springer.
• 22. Deshmukh, A.A. and R. Ranganathan, Recent advances in modelling structure-property correlations in high-entropy alloys. Journal of Materials Science & Technology, 2024.
• 23. Hsu, W.-L., et al., Clarifying the four core effects of high-entropy materials. Nature Reviews Chemistry, 2024: p. 1-15.
• 24. Wang, H., et al., Multifunctional high entropy alloys enabled by severe lattice distortion. Advanced Materials, 2024. 36(17): p. 2305453.
• 25. Li, K. and W. Chen, Recent progress in high-entropy alloys for catalysts: synthesis, applications, and prospects. Materials Today Energy, 2021. 20: p. 100638.
• 26. Yao, Y., et al., High-throughput, combinatorial synthesis of multimetallic nanoclusters. Proceedings of the National Academy of Sciences, 2020. 117(12): p. 6316-6322.
• 27. Ashwini, R., et al., Optimization of NiFeCrCoCu high entropy alloy nanoparticle–graphene (HEA-G) composite for the enhanced electrochemical sensitivity towards urea oxidation. Journal of Alloys and Compounds, 2022. 903: p. 163846.
• 28. Pavithra, C.L., et al., Graphene oxide reinforced magnetic FeCoNiCuZn high entropy alloy through electrodeposition. Journal of The Electrochemical Society, 2022. 169(2): p. 022501.
• 29. Phakatkar, A.H., et al., Ultrafast synthesis of high entropy oxide nanoparticles by flame spray pyrolysis. Langmuir, 2021. 37(30): p. 9059-9068.
• 30. Zhang, Y. and Y. Yue, Simulation and Calculation for Predicting Structures and Properties of High-Entropy Alloys, in High Entropy Materials-Microstructures and Properties. 2022, IntechOpen.
• 31. Li, H., et al., Enhanced plasticity in refractory high-entropy alloy via multicomponent ceramic nanoparticle. Journal of Materials Science & Technology, 2024.
• 32. Yin, Y., et al., In-situ synthesized age-hardenable high-entropy composites with superior wear resistance. Composites Part B: Engineering, 2022. 235: p. 109795.
• 33. Jung, S.-G., et al., High critical current density and high-tolerance superconductivity in high-entropy alloy thin films. Nature communications, 2022. 13(1): p. 3373.
• 34. Feng, R., et al., Superior high‐temperature strength in a supersaturated refractory high‐entropy alloy. Advanced materials, 2021. 33(48): p. 2102401.
• 35. Wan, K., H. Wang, and X. Shi, Machine Learning-Accelerated High-Throughput Computational Screening: Unveiling Bimetallic Nanoparticles with Peroxidase-Like Activity. ACS nano, 2024.
• 36. Singh, R., et al., Accelerating computational modeling and design of high-entropy alloys. Nature Computational Science, 2021. 1(1): p. 54-61.
• 37. Zhang, S., et al., Hydrogen adsorption on ordered and disordered Pt-Ni alloys. Topics in Catalysis, 2020. 63(7): p. 714-727.
• 38. Cui, Z., X. Zhou, and Q. Meng, Atomic-scale mechanism investigation of mass transfer in laser fabrication process of Ti-Al alloy via molecular dynamics simulation. Metals, 2020. 10(12): p. 1660.
• 39. Wang, S., Atomic structure modeling of multi-principal-element alloys by the principle of maximum entropy. Entropy, 2013. 15(12): p. 5536-5548.
• 40. Long, Y., et al., Enhanced strength of a mechanical alloyed NbMoTaWVTi refractory high entropy alloy. Materials, 2018. 11(5): p. 669.
• 41. Xiang, H., et al., High-entropy ceramics: Present status, challenges, and a look forward. Journal of Advanced Ceramics, 2021. 10: p. 385-441.
• 42. Li, W., et al., Mechanical behavior of high-entropy alloys. Progress in Materials Science, 2021. 118: p. 100777.
• 43. Chao, Q., et al., AlxCoCrFeNi high entropy alloys from metal scrap: Microstructure and mechanical properties. Journal of Alloys and Compounds, 2024. 976: p. 173002.
• 44. Sathiyamoorthi, P. and H.S. Kim, High-entropy alloys with heterogeneous microstructure: processing and mechanical properties. Progress in Materials Science, 2022. 123: p. 100709.
• 45. Abdelmonem, A., E. Echeweozo, and D. Igwesi, Evaluation of shielding and interaction properties of different stainless steel alloys for nuclear power plant shielding. Radiation Effects and Defects in Solids, 2024: p. 1-24.
• 46. Pang, J., et al., High-temperature structural and mechanical stability of refractory high-entropy alloy Nb40Ti25Al15V10Ta5Hf3W2. Materials Characterization, 2023. 205: p. 113321.
• 47. Cao, J., et al., Exceptional thermal stability of nanostructured FeCoNiCrCu high entropy alloy facilitated by unusual grain boundary segregation. Scripta Materialia, 2023. 234: p. 115545.
• 48. Mobarakeh, S.A.E., T. Seyedhosseini, and K. Dehghani, Tribological and mechanical properties of surface nanocomposite AlCoCrFeNi2. 1 high-entropy alloy produced by FSP. Journal of Alloys and Compounds, 2022. 896: p. 163052.
• 49. Ye, X., et al., Carbon nanotubes (CNTs) reinforced CoCrMoNbTi0. 4 refractory high entropy alloy fabricated via laser additive manufacturing: processing optimization, microstructure transformation and mechanical properties. Crystals, 2022. 12(11): p. 1678.
• 50. Han, B., et al., Microstructure and wear behavior of laser clad interstitial CoCrFeNi high entropy alloy coating reinforced by carbon nanotubes. Surface and Coatings Technology, 2022. 434: p. 128241.
• 51. Li, Y., et al., Integration of hardness and toughness in (CuNiTiNbCr) Nx high entropy films through nitrogen-induced nanocomposite structure. Scripta Materialia, 2024. 238: p. 115763.
• 52. Xu, D., X. Wang, and Y. Lu, Heterogeneous‐Structured Refractory High‐Entropy Alloys: A Review of State‐of‐the‐Art Developments and Trends. Advanced Functional Materials, 2024: p. 2408941.
• 53. Wang, L., et al., A Review of High-Temperature Toughness Improvement Strategies for Medium Entropy Alloys. Journal of Materials Engineering and Performance, 2024. 33(5): p. 2051-2063.
• 54. Zhou, Y., et al., A strong-yet-ductile high-entropy alloy in a broad temperature range from cryogenic to elevated temperatures. Acta Materialia, 2024: p. 119770.
• 55. Chen, X., et al., Novel refractory high-entropy metal-ceramic composites with superior mechanical properties. International Journal of Refractory Metals and Hard Materials, 2024. 119: p. 106524.
• 56. Wu, H.-H., et al., Local chemical ordering coordinated thermal stability of nanograined high-entropy alloys. Rare Metals, 2023. 42(5): p. 1645-1655.
• 57. Zhang, B., et al., Refractory high-entropy alloys fabricated by powder metallurgy: Progress, challenges and opportunities. Journal of Science: Advanced Materials and Devices, 2024: p. 100688.
• 58. Tukac, O.U., A. Ozalp, and E. Aydogan, Development and thermal stability of Cr10Mo25Ta25Ti15V25 refractory high entropy alloys. Journal of Alloys and Compounds, 2023. 930: p. 167386.
• 59. Wan, Y., et al., A Nitride-Reinforced NbMoTaWHfN Refractory High-Entropy Alloy with Potential Ultra-High-Temperature Engineering Applications. Engineering, 2023. 30: p. 110-120.
• 60. Rogal, Ł., D. Kalita, and L. Litynska-Dobrzynska, CoCrFeMnNi high entropy alloy matrix nanocomposite with addition of Al2O3. Intermetallics, 2017. 86: p. 104-109.
• 61. Liu, J., et al., Research progress on the influence of alloying elements on the corrosion resistance of high-entropy alloys. Journal of Alloys and Compounds, 2024: p. 175394.
• 62. Fu, Y., et al., Recent advances on environmental corrosion behavior and mechanism of high-entropy alloys. Journal of Materials Science & Technology, 2021. 80: p. 217-233.
• 63. Sharma, A., High entropy alloy coatings and technology. Coatings, 2021. 11(4): p. 372.
• 64. Liang, J., et al., Corrosion resistance and mechanism of high‐entropy alloys: A review. Materials and Corrosion, 2024. 75(4): p. 424-432.
• 65. Anamu, U., et al., Fundamental design strategies for advancing the development of high entropy alloys for thermo-mechanical application: A critical review. Journal of Materials Research and Technology, 2023.
• 66. Yan, X., et al., Al0. 3CrxFeCoNi high-entropy alloys with high corrosion resistance and good mechanical properties. Journal of Alloys and Compounds, 2021. 860: p. 158436.
• 67. Godlewska, E.M., et al., Corrosion of Al (Co) CrFeNi high-entropy alloys. Frontiers in Materials, 2020. 7: p. 566336.
• 68. Shi, Y., et al., Homogenization of AlxCoCrFeNi high-entropy alloys with improved corrosion resistance. Corrosion Science, 2018. 133: p. 120-131.
• 69. Pratskova, S., et al., Corrosion resistance of Al x CoCrFeNiM (M= Ti, V, Si, Mn, Cu) high entropy alloys in NaCl and H2SO4 solutions. Metals, 2022. 12(2): p. 352.
• 70. Li, M., et al., Towards high-entropy alloys with high-temperature corrosion resistance and structural stability. Journal of Materials Science & Technology, 2024. 174: p. 133-144.
• 71. Mohanty, G.C., et al., Enhanced energy density of high entropy alloy (Fe‐Co‐Ni‐Cu‐Mn) and green graphene hybrid supercapacitor. Energy Storage, 2024. 6(4): p. e668.
• 72. Shi, Y., et al., Interfacial engineering for enhanced mechanical performance: High-entropy alloy/graphene nanocomposites. Materials Today Physics, 2023. 38: p. 101220.
• 73. Xu, H., et al., In-situ assembly from graphene encapsulated CoCrFeMnNi high-entropy alloy nanoparticles for improvement corrosion resistance and mechanical properties in metal matrix composites. Journal of Alloys and Compounds, 2019. 811: p. 152082.
• 74. Eskandarkolaie, M.B., et al., Reduced graphene oxide (rGO) reinforced CoCrFeNiMn high entropy alloy: Microstructure, mechanical properties, and corrosion behavior. Ceramics International, 2024.
• 75. Aliyu, A. and C. Srivastava, Microstructure and corrosion properties of MnCrFeCoNi high entropy alloy-graphene oxide composite coatings. Materialia, 2019. 5: p. 100249.
• 76. Aliyu, A., M. Rekha, and C. Srivastava, Microstructure-electrochemical property correlation in electrodeposited CuFeNiCoCr high-entropy alloy-graphene oxide composite coatings. Philosophical Magazine, 2019. 99(6): p. 718-735.
• 77. Singh, D., U. Pandel, and R.K. Duchaniya, Graphene oxide reinforced high entropy alloy (CuNiFeCrMo-GO) nanocomposite coating deposited by electroless coating method on mild steel. Materials Today: Proceedings, 2020. 28: p. 2411-2417.
• 78. Rehm, T.E., Advanced nuclear energy: the safest and most renewable clean energy. Current Opinion in Chemical Engineering, 2023. 39: p. 100878.
• 79. Moschetti, M., et al., Design considerations for high entropy alloys in advanced nuclear applications. Journal of Nuclear Materials, 2022. 567: p. 153814.
• 80. Yang, H., et al., Development of reduced-activation and radiation-resistant high-entropy alloys for fusion reactor. International Journal of Refractory Metals and Hard Materials, 2024: p. 106674.
• 81. Xu, Q., et al., Crack-healing mechanisms in high-entropy alloys under ion irradiation. Acta Materialia, 2024. 263: p. 119488.
• 82. Cheng, Z., et al., Irradiation effects in high-entropy alloys and their applications. Journal of Alloys and Compounds, 2023. 930: p. 166768.
• 83. Solov’yov, A.V., et al., Condensed Matter Systems Exposed to Radiation: Multiscale Theory, Simulations, and Experiment. Chemical reviews, 2024.
• 84. Yaykaşlı, H., et al., CoCrFeNiSi high entropy alloy: Synthesis, structural and radiation shielding properties. Progress in Nuclear Energy, 2023. 165: p. 104930.
• 85. Sakar, E., et al., A comprehensive study on structural properties, photon and particle attenuation competence of CoNiFeCr-Ti/Al high entropy alloys (HEAs). Journal of Alloys and Compounds, 2023. 931: p. 167561.
• 86. Şimşek, T., et al., FeCoNiMnCr high-entropy alloys (HEAs): Synthesis, structural, magnetic and nuclear radiation absorption properties. Ceramics International, 2023. 49(15): p. 25364-25370.
• 87. Sakar, E., et al., Effect of oxidation on radiation shielding capacity of ZrNbTaMoW Refractory High Entropy Alloys (RHEA) for nuclear reactor applications: Experimental and theoretical assessment. Journal of Alloys and Compounds, 2024. 997: p. 174917.
• 88. Güler, S.H., et al., Exploring critical behavioral differences in physical, structural, and nuclear radiation attenuation properties of produced High Entropy Alloy (HEA) and Refractory-High Entropy Alloy (RHEA) samples. Current Applied Physics, 2024. 58: p. 1-10.
• 89. Subedi, B., J. Paudel, and T.R. Lamichhane, Gamma-ray, fast neutron and ion shielding characteristics of low-density and high-entropy Mg–Al–Ti–V–Cr–Fe–Zr–Nb alloy systems using Phy-X/PSD and SRIM programs. Heliyon, 2023. 9(7).
• 90. Devakul, T., et al., Magic-angle helical trilayer graphene. Science Advances, 2023. 9(36): p. eadi6063.
• 91. Bahri, M., et al., Recent advances in chemical vapour deposition techniques for graphene-based nanoarchitectures: From synthesis to contemporary applications. Coordination Chemistry Reviews, 2023. 475: p. 214910.
• 92. Kausar, A., Potential of polymer/graphene nanocomposite in electronics. American Journal of Nanoscience and Nanotechnology Research, 2018. 6(1): p. 55-63.
• 93. Zandiatashbar, A., et al., Effect of defects on the intrinsic strength and stiffness of graphene. Nature communications, 2014. 5: p. 3186.
• 94. Pei, S. and H.-M. Cheng, The reduction of graphene oxide. Carbon, 2012. 50(9): p. 3210-3228.
• 95. Mohan, V.B., et al., Graphene-based materials and their composites: A review on production, applications and product limitations. Composites Part B: Engineering, 2018. 142: p. 200-220.
• 96. Zare, Y., N. Gharib, and K.Y. Rhee, Influences of graphene morphology and contact distance between nanosheets on the effective conductivity of polymer nanocomposites. Journal of Materials Research and Technology, 2023.
• 97. Pei, Q.-X., et al., Enhancing the impact property of high-entropy alloys with graphene layers: a molecular dynamics study. Journal of Materials Science, 2023. 58(48): p. 18105-18119.
• 98. Gul, A.O., et al., Graphene nanoplatelet-reinforced high entropy alloys (HEAs) through B4C incorporation: structural, physical, mechanical, and nuclear shielding properties. Applied Physics A, 2023. 129(10): p. 713.
• 99. Dong, X., et al., A new phase from compression of carbon nanotubes with anisotropic Dirac fermions. Scientific reports, 2015. 5(1): p. 1-7.
• 100. Lin, Y., et al., Scaling aligned carbon nanotube transistors to a sub-10 nm node. Nature Electronics, 2023. 6(7): p. 506-515.
• 101. Al Tahhan, A.B., et al., Effect of induced vacancy defects on the mechanical behavior of wavy single-walled carbon nanotubes. Nano Trends, 2023. 3: p. 100016.
• 102. Tyagi, S. and S. Negi, Calculation of Density of States of Pristine and Functionalized Carbon Nanotubes: A DFT Approach. Indian Journal of Science and Technology, 2023. 16(40): p. 3567-3574.
• 103. Mishra, S., et al., Carbon Nanotube–Synthesis, Purification and Biomedical Applications. Current Nanomaterials, 2023. 8(4): p. 328-335.
• 104. Liu, D., et al., Functionalization of carbon nanotubes for multifunctional applications. Trends in Chemistry, 2024.
• 105. Li, H., et al., Industrial Scale Manufacturing Sub‐10 nm Reverse Osmotic Desalination Membrane on Metallic Single‐Walled Carbon Nanotubes Network. Advanced Materials Interfaces, 2024: p. 2400168.
• 106. Bahrami, A., A. Mohammadnejad, and M. Sajadi, Microstructure and mechanical properties of spark plasma sintered AlCoFeMnNi high entropy alloy (HEA)-carbon nanotube (CNT) nanocomposite. Journal of Alloys and Compounds, 2021. 862: p. 158577.
• 107. Parizi, M.T., et al., Trimodal hierarchical structure in the carbonaceous hybrid (GNPs+ CNTs) reinforced CoCrFeMnNi high entropy alloy to promote strength-ductility synergy. Materials Science and Engineering: A, 2022. 850: p. 143446.
• 108. Taylor, E.W. Organics, polymers and nanotechnology for radiation hardening and shielding applications. in Nanophotonics and Macrophotonics for Space Environments. 2007. SPIE.
• 109. Zhang, X., et al., A novel (La0. 2Ce0. 2Gd0. 2Er0. 2Tm0. 2) 2 (WO4) 3 high-entropy ceramic material for thermal neutron and gamma-ray shielding. Materials & Design, 2021. 205: p. 109722.
• 110. Wang, K., et al., Flexible low‐melting point radiation shielding materials: soft elastomers with GaInSnPbBi high‐entropy alloy inclusions. Macromolecular Materials and Engineering, 2021. 306(12): p. 2100457.
• 111. Guo, Y.-X., et al., Correlations between valence electron concentration and the phase stability, intrinsic strength, and deformation mechanism in fcc multicomponent alloys. Physical Review B, 2024. 109(2): p. 024102.
• 112. Cvijović-Alagić, I., et al. Novel high entropy alloys for extreme environments. in IMEC2024-2nd International Conference on Innovative Materials in Extreme Conditions: Book of abstracts. 2024. Belgrade: Vinča Institute of Nuclear Sciences-National Institute of thе ….
• 113. Kar, N., et al., Retrosynthetic design of core–shell nanoparticles for thermal conversion to monodisperse high-entropy alloy nanoparticles. Nature Synthesis, 2024. 3(2): p. 175-184.
• 114. Gul, A.O., et al., Newly synthesized NiCoFeCrW High-Entropy Alloys (HEAs): Multiple impacts of B4C additive on structural, mechanical, and nuclear shielding properties. Intermetallics, 2022. 146: p. 107593.
• 115. Kavaz, E., et al., Boron nitride nanosheet-reinforced WNiCoFeCr high-entropy alloys: the role of B4C on the structural, physical, mechanical, and radiological shielding properties. Applied Physics A, 2022. 128(8): p. 694.
• 116. Ruan, X., et al., Conducted Electromagnetic Interference in Power Converters: Modeling, Prediction and Reduction. 2024: Springer Nature.
• 117. Maruthi, N., M. Faisal, and N. Raghavendra, Conducting polymer based composites as efficient EMI shielding materials: A comprehensive review and future prospects. Synthetic Metals, 2021. 272: p. 116664.
• 118. Mamatha, G., et al., Polymer based Composites for Electromagnetic Interference (EMI) Shielding: The Role of Magnetic Fillers in Effective Attenuation of Microwaves, a Review. Hybrid Advances, 2024: p. 100200.
• 119. Hu, J., et al., Novel Carbonitriding Process of High-Entropy Alloys Using Mechanochemical Process for Obtaining Excellent High-frequency Electromagnetic Properties. Carbon, 2024: p. 119406.
• 120. Zhang, Y., et al., Electromagnetic interference shielding effectiveness of high entropy AlCoCrFeNi alloy powder laden composites. Journal of Alloys and Compounds, 2018. 734: p. 220-228.
• 121. Duan, Y., et al., FeCoNiCuAl high entropy alloys microwave absorbing materials: Exploring the effects of different Cu contents and annealing temperatures on electromagnetic properties. Journal of Alloys and Compounds, 2020. 848: p. 156491.
• 122. Duan, Y., et al., Optimized microwave absorption properties of FeCoCrAlGdx high-entropy alloys by inhibiting nanograin coarsening. Journal of Alloys and Compounds, 2022. 921: p. 166088.
• 123. Yang, J., et al., Enhanced electromagnetic-wave absorbing performances and corrosion resistance via tuning Ti contents in FeCoNiCuTi x high-entropy alloys. ACS Applied Materials & Interfaces, 2022. 14(10): p. 12375-12384.
• 124. Zhou, H., et al., Structure evolution and electromagnetic-wave absorption performances of multifunctional FeCoNiMnVx high entropy alloys with harsh-environment resistance. Journal of Alloys and Compounds, 2023. 946: p. 169402.
• 125. Huang, L., et al., Novel broadband electromagnetic-wave absorption metasurfaces composed of C-doped FeCoNiSiAl high-entropy-alloy ribbons with hierarchical nanostructures. Composites Part B: Engineering, 2022. 244: p. 110182.
• 126. Mohammadabadi, F.H., et al., Electromagnetic microwave absorption properties of high entropy spinel ferrite ((MnNiCuZn) 1− xCoxFe2O4)/graphene nanocomposites. Journal of Materials Research and Technology, 2021. 14: p. 1099-1111.
• 127. Yu, Y., et al., High-entropy Pt18Ni26Fe15Co14Cu27 nanocrystalline crystals in situ grown on reduced graphene oxide with excellent electromagnetic absorption properties. Journal of Colloid and Interface Science, 2023. 639: p. 193-202.
• 128. Wang, S., et al., Effect of Reduced Graphene Oxide on Microwave Absorbing Properties of Al1. 5Co4Fe2Cr High-Entropy Alloys. Entropy, 2024. 26(1): p. 60.
• 129. Zhang, Y., et al., High-Entropy Alloy Nanoparticles combining SiC coating Synergistically Boost Electromagnetic Shielding Performance of Carbon Nanotube Sponge. Journal of Materials Chemistry A, 2024.
• 130. Zhang, F., et al., Microwave absorption properties and mechanism analyses of core-shell structured high-entropy oxides coated with PPy. Journal of Alloys and Compounds, 2024. 988: p. 174151.
• 131. Hu, Y., et al., Cf@ BN/(CrZrHfNbTa) C-SiC high-entropy ceramic matrix composites with outstanding electromagnetic interference shielding and high-temperature resistance. Ceramics International, 2024.