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Thermodynamics and nanotechnology for 5G communication technology and energy harvesting

ABSTRACT
5G communication technology has been skyrocketing, and has changed everything in our daily lives, and its applications in various fields are also promising. However, the thermal conductivity/dissipation problems of highly integrated electronic devices and electrical equipment are becoming more and more prominent, and thermodynamics offers a solution, and fractal meta-surfaces provides an extremely efficient approach to transfer the generated waste heat, which can be used for thermal energy harvesting, and a fractal thermodynamic model is developed for thermal management.
KEYWORDS
PAPER SUBMITTED: 2024-03-05
PAPER REVISED: 2024-03-22
PAPER ACCEPTED: 2024-03-22
PUBLISHED ONLINE: 2024-04-14
DOI REFERENCE: https://doi.org/10.2298/TSCI240305102Z
REFERENCES
  1. Andrews, JG; et al., What Will 5G Be? IEEE Journal om Selected Areas in Communications, 32(2014), No.6, pp.1065-1082
  2. McNair, J., The 6G frequency switch that spares scientific services, Nature, 606(2022), Jun., pp. 34-35
  3. Kanno, A., Seamless Convergence Between Terahertz Radios and Optical Fiber Communication Toward 7G Systems, IEEE Journal of Selected Topics in Quantum Electronics, 29(2023), No.5, 8600509
  4. Qian, X., et al., Thermodynamics of Ionic Thermoelectrics for Low-Grade Heat Harvesting, ACS Energy Letters, 9(2024), No.2, pp.679-706
  5. Ge, X., et al., 5G Ultra-Dense Cellular Networks, IEEE Wireless Communications, 23(2016), 1, pp. 72-79
  6. Liu, S.B ., et al., Efforts Toward the Fabrication of Thermoelectric Cooling Module Based on N-Type and P-Type PbTe Ingots, Advanced Functional Materials, 2024, DOI10.1002/adfm.202315707
  7. Heidari, H., et al., Energy Harvesting and Power Management for IoT Devices in the 5G Era, IEEE Communications Magazine, 59(2021), No.9, pp.91-97
  8. Hu, S.Y., et al., Modeling and Analysis of Energy Harvesting and Smart Grid-Powered Wireless Communication Networks: A Contemporary Survey, IEEE Transactions on Green Communications and Networking, 4(2020), No.2, pp.461-496
  9. Lin, Y., et al., Flexible, Highly Thermally Conductive and Electrically Insulating Phase Change Materials for Advanced Thermal Management of 5G Base Stations and Thermoelectric Generators, Nano-Micro Letters, 15(2023), No.1, Article Number 31
  10. Xu, Z.P. and Wang, K.J., An analytical thermal model for the 3-D integrated circuit with new-type through silicon via, Thermal Science, 27(2023), No.3B, pp.2391-2398
  11. Tang, L., et al., Flexible and Robust Functionalized Boron Nitride/Poly(p-Phenylene Benzobisoxazole) Nanocomposite Paper with High Thermal Conductivity and Outstanding Electrical Insulation, Nano-Micro Letters, 16 (2024), No.1, Article Number 38
  12. He, M.K., et al., Shape Anisotropic Chain-Like CoNi/Polydimethylsiloxane Composite Films with Excellent Low-Frequency Microwave Absorption and High Thermal Conductivity, Advanced Functional Materials, 2024, DOI10.1002/adfm.202316691
  13. Han, Y.X., et al., Highly Thermally Conductive Aramid Nanofiber Composite Films with Synchronous Visible/Infrared Camouflages and Information Encryption, Angewandte Chemie-International Edition, 2024, DOI10.1002/anie.202401538FEB 2024
  14. Liu, G.L., et al., Last Patents on Bubble Electrospinning, Recent Patents on Nanotechnology, 14(2020), No.1, pp.5-9
  15. Zuo, Y.T. and Liu, H.J., Effect of temperature on the bubble-electrospinning process and its hints for 3-D printing technology , Thermal Science, 26(2022), No.3, pp.2499-2503
  16. Wan, L.Y., Bubble Electrospinning and Bubble-spun Nanofibers, Recent Patents on Nanotechnology, 14(2020), No.1, pp.10-13
  17. Liu, H.Y., et al., Interaction of multiple jets in bubble electrospinning, Thermal Science, 27(2023), 3A, pp.1741-1746
  18. Ali, M. and He, J.H., Bipolymer nanofibers: Engineering nanoscale Interface via bubble electrospinning, Journal of Applied Polymer Science, 141(2023), No.5,DOI10.1002/app.54878
  19. Wang, Z.X., et al., High-quality semiconductor fibres via mechanical design, Nature, 626(2024), Feb., DOI10.1038/s41586-023-06946-0
  20. Lv, Q.N., et al., Three-Dimensional Printing to Fabricate Graphene-Modified Polyolefin Elastomer Flexible Composites with Tailorable Porous Structures for Electromagnetic Interference Shielding and Thermal Management Application, Industrial & Engineering Chemistry Research, 61(2022), No.45, pp.16733-16746
  21. Tavares, J., et al., Flexible Textile Antennas for 5G Using Eco-Friendly Water-Based Solution and Scalable Printing Processes, Advanced Materials Technologies, 2024, DOI10.1002/admt.202301499
  22. Zhang, C., et al., An optically semi-transparent liquid antenna with slot-coupled feeding for future wireless communication systems, AEU-International Journal of Electronics and Communications, 175(2024), Jan., Article Number 155047
  23. Khosravi, A., et al., Waste heat recovery from a data centre and 5G smart poles for low-temperature district heating network, Energy, 218(2021), Mar., 119468
  24. Banotra, A.,et al., Energy harvesting in self-sustainable IoT devices and applications based on cross-layer architecture design: A survey, Computer Networks, 236(2023), Sep., 110011
  25. Haeri, S.Z., et al., Review on Stability, Thermophysical Properties, and Solar Harvesting Applications of Titanium Nitride-Based Nanofluids: Current Status and Outlook, Energy & Fuels, 2024, DOI10.1021/acs.energyfuels.3c03360
  26. Hyemin Kim, Jeonggyun Ham, Nayoung You, Geunho Gim, Honghyun Cho, Enhancing solar thermal energy harvesting efficiency and temperature uniformity of Fe3O4 nanofluid in receiver of direct solar thermal collector using dynamic magnetic field, Applied Thermal Engineering, 236(2024), Part C, 121744,
  27. He, J.H., Abd-Elazem, N.Y., The carbon nanotube-embedded boundary layer theory for energy harvesting, Facta Universitatis Series: Mechanical Engineering, 20(2022), No.2, pp.211-235
  28. Kou, S.J., et al., Fractal boundary layer and its basic properties, Fractals, 30(2022), No. 09, 2250172
  29. Zhang, P.L. and Wang, K.J., A new fractional thermal model for the Cu/low-k interconnects in nanometer integrated circuit, Thermal Science, 26(2022), No.3, pp.2413-2418
  30. Khosravi, A., et al., An artificial intelligence based-model for heat transfer modeling of 5G smart poles, Case Studies in Thermal Engineering, 28(2021), Dec., 101613
  31. Fan, J. and Shang, X.M., Fractal heat transfer in wool fiber hierarchy, Heat Transfer Research, 44(2013), No.5, pp.399-407
  32. Liu, H., et al., A one dimensional heat transfer model for wolverine (gulo-gulo) hair", International Journal of Clothing Science and Technology, 30(2018), No. 4, pp. 548-558
  33. Goyal, N., Panwar, R., Minkowski inspired circular fractal metamaterial microwave absorber for multiband applications, Applied Physics A, 129(2023), No.4, 293
  34. Sabban, A. Novel Meta-Fractal Wearable Sensors and Antennas for Medical, Communication, 5G, and IoT Applications, Fractal and Fractional, 8(2024), No.2, Article Number 100
  35. Duan, Y.P., et al., Layered metamaterials with Sierpinski triangular fractal metasurface: Compatible stealth for S-band radar and infrared, Materials Today Physics, 38(2023), Nov., 101210
  36. He, C.H., Liu, C., Fractal dimensions of a porous concrete and its effect on the concrete's strength, Facta Universitatis Series: Mechanical Engineering,21(2023), No.1, pp.137-150;
  37. He, C.H., et al., A novel bond stress-slip model for 3-D printed concretes, Discrete and Continuous dynamical Systems, 2021, DOI10.3934/dcdss.2021161
  38. Liu, H., et al., Influence of pore defects on the hardened properties of 3D printed concrete with coarse aggregate, Additive Manufacturing. (2022) 102843, DOI10.1016/j.addma.2022.102843
  39. Zhao, L., et al., Promises and challenges of fractal thermodynamics, Thermal Science, 27(2023), No. 3A , pp.1735-1740
  40. Sun, J.S., Fractal modification of Schrodinger equation and its fractal variational principle, Thermal Science, 27(2023), No.3A , pp.2029-2037
  41. Liu, F.L., et al., A fractal solution of Camassa-Holm and Degasperis-Procesi models under two-scale dimension approach, Fractals, 31(2023), No.5, 2350053
  42. Lu, J., Application of Variational Principle and Fractal Complex Transformation to (3+1)-Dimensional Fractal Potential-YTSF Equation, Fractals, 32 (2024), 1, 2450027