Abstract
Surface plasmons with MHz-GHz energies are predicted by using milliparticles made of metamaterials that behave like metals in the radiofrequency range. In this work, the so-called radioplasmonics is exploited to design scatterers embedded in different realistic media with tunable absorption or scattering properties. High-quality scattering/absorption based on plasmon excitation is demonstrated through a few simple examples, useful to build antennas with better performance than conventional ones. Systems embedded in absorbing media as saline solutions or biological tissues are also considered to improve biomedical applications and contribute with real-time, in vivo monitoring tools in body tissues. In this regard, any possible implementation is criticized by calculating the radiofrequency heating with full thermal simulations. As proof of the versatility offered by radioplasmonic systems, plasmon “hybridization” is used to enhance near-fields to unprecedented values or to tune resonances as in optical spectra, minimizing the heating effects. Finally, a monitorable drug-delivery in human tissue is illustrated with a hypothetical example. This study has remarkable consequences on the conception of plasmonics at macroscales. The recently developed concept of “spoof” plasmons achieved by complicated structures is simplified in radioplasmonics since bulk materials with elemental geometries are considered.
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Abbreviations
- EM:
-
Electromagnetic
- MM/s:
-
Metamaterial/s
- RF:
-
Radiofrequency
- RFID:
-
Radiofrequency Identification
- NFC:
-
Near-field Communication
- SPs:
-
Spoof plasmons
- RP:
-
Radioplasmonic
- GHz:
-
Gigahertz
- MHz:
-
Megahertz
- CW:
-
Continuous wave
- PDMS:
-
Polydimethylsiloxane
- APu/Al:
-
Acrylic/polyurethane/aluminum
- MWCNT:
-
Multi-walled carbon nanotubes
- CNF:
-
Carbon nanofiber
- NiO:
-
Nickel oxide
- TiN:
-
Titanium nitride
- PPy:
-
Polypyrrole
- CNTs:
-
Carbon nanotubes
- SI:
-
Supplementary Information
- SRPs:
-
Surface radioplasmons
- DI:
-
Distilled
- BS:
-
Composition of Bi203 and Si02
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Acknowledgements
RMAE would like to thank Dr. Cristian D’Angelo from IFAS-UNCPBA and Dr. Francesco De Angelis from IIT for stimulating discussions on the topic. The author also thank Plasmon Nanotechnologies group for their hospitality in IIT and the permission to use their licensed software.
Funding
This research was supported by Facultad de Ciencias Exactas, Universidad Nacional del Centro de la Provincia de Buenos Aires from Argentina and Istituto Italiano di Tecnologia from Italy.
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R.M.A.E. conceived the idea, made of the calculations, analyzed the results, and wrote the manuscript.
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Abraham-Ekeroth, R.M. Radioplasmonics: Design of Metamaterial Milli-particles in Air and Absorbing Media for Antenna Communication and Human-Body In Vivo Applications. Plasmonics 16, 2179–2191 (2021). https://doi.org/10.1007/s11468-021-01471-0
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DOI: https://doi.org/10.1007/s11468-021-01471-0