The single-wall carbon nanotube waveguides and excitation of their σ+π plasmons by an electron beam

Nejati, M.; Javaherian, C.; Shokri, Babak; Jazi, B.

doi:10.1063/1.3077306

Cited by 19 publications

(10 citation statements)

References 27 publications

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“…About our article, 9 Moradi 10 had a comment on our work but in response to the comment article, 11 in which we did not agree with their points except for a misprinted formula, which was correctly considered in drawing the curves of Ref. 9 and published as an erratum. 12 In addition, part II of Ref.…”

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confidence: 67%

Response to “Comment on ‘Study of geometrical effects on the characteristics of metallic double-walled carbon nanotube waveguides through quantum hydrodynamics’ ” [Phys. Plasmas 16, 084703 (2009)]

2009

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mentioning

confidence: 67%

Response to “Comment on ‘Study of geometrical effects on the characteristics of metallic double-walled carbon nanotube waveguides through quantum hydrodynamics’ ” [Phys. Plasmas 16, 084703 (2009)]

2009

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“…The oscillation of induced longitudinal electric field reminds that in a sequence of a multi-cell RF cavity operating at π-mode. The excitation of surface plasmonic modes [55,56] can be driven either by charged particle beam [57] or by laser [58]. To be effective, the driver dimensions should match the spatial (∼ nm) and time (sub-femtoseconds) scales of the excited plasmonic oscillations.…”

Section: Plasmonic Accelerationmentioning

confidence: 99%

Long-term future particle accelerators

Resta-López¹

2022

Preprint

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Particle accelerators have enabled forefront research in high energy physics and other research areas for more than half a century. Accelerators have directly contributed to 26 Nobel Prizes in Physics since 1939 as well as another 20 Nobel Prizes in Chemistry, Medicine and Physics with X-rays. Although high energy physics has been the main driving force for the development of the particle accelerators, accelerator facilities have continually been expanding applications in many areas of research and technology. For instance, active areas of accelerator applications include radiotherapy to treat cancer, production of short-lived medical isotopes, synchrotron light sources, free-electron lasers, beam lithography for microcircuits, thin-film technology and radiation processing of food. Currently, the largest and most powerful accelerator is the Large Hadron Collider (LHC) at CERN, which accelerates protons to multi-TeV energies in a 27 km high-vacuum ring. To go beyond the maximum capabilities of the LHC, the next generation of circular and linear particle colliders under consideration, based on radiofrequency acceleration, will require multi-billion investment, kilometric infrastructure and a massive power consumption. These factors pose serious challenges in an increasingly resource-limited world. Therefore, it is important to look for alternative and sustainable acceleration techniques. This review article pays special attention to novel accelerator techniques to overcome present acceleration limitations towards more compact and cost-effective long term future accelerators. KeywordsHigh energy collider • Plasma wakefield • Dielectric accelerator • Solid-state plasma • Plasmonic accelerator * The author acknowledges support by the Generalitat Valenciana under Grant agreement No. CIDEGENT/2019/058.

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“…4,5 Another property that only belongs to the metallic CNTs is the ability to conduct surface plasmon ͑SP͒ waves. 6,7 SPs are collective electronic excitations of free electrons of metal surface which are caused by an intimate interaction between electrons and electromagnetic waves.…”

Section: Study Of Geometrical Effects On the Characteristics Of Metalmentioning

confidence: 99%

Study of geometrical effects on the characteristics of metallic double-walled carbon nanotube waveguides through quantum hydrodynamics

2009

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Articles you may be interested inSimple model of bulk and surface excitation effects to inelastic scattering in low-energy electron beam irradiation of multi-walled carbon nanotubes Response to "Comment on 'Study of geometrical effects on the characteristics of metallic double-walled carbon nanotube waveguides through quantum hydrodynamics'" [Phys. Plasmas16, 084703 (2009)] Phys. Plasmas 16, 084704 (2009); 10.1063/1.3212886 Comment on "Study of geometrical effects on the characteristics of metallic double-walled carbon nanotube waveguides through quantum hydrodynamics" [Phys. Plasmas16, 063501 (2009)] Phys. Plasmas 16, 084703 (2009); 10.1063/1.3212885Hysteretic transfer characteristics of double-walled and single-walled carbon nanotube field-effect transistors By assuming the metallic double-walled carbon nanotubes as two coaxial free electron gas layers with linearized hydrodynamic model, it is shown that surface plasmons coupled with electromagnetic fields can be excited on a metallic double-walled carbon nanotube and propagate along its axis. Dispersion relations of surface plasmons for E-type and B-type waves in various inner-outer radii and various interlayer distances for long metallic double-walled carbon nanotubes are obtained.

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The single-wall carbon nanotube waveguides and excitation of their σ+π plasmons by an electron beam

Cited by 19 publications

References 27 publications

Response to “Comment on ‘Study of geometrical effects on the characteristics of metallic double-walled carbon nanotube waveguides through quantum hydrodynamics’ ” [Phys. Plasmas 16, 084703 (2009)]

Response to “Comment on ‘Study of geometrical effects on the characteristics of metallic double-walled carbon nanotube waveguides through quantum hydrodynamics’ ” [Phys. Plasmas 16, 084703 (2009)]

Long-term future particle accelerators

Study of geometrical effects on the characteristics of metallic double-walled carbon nanotube waveguides through quantum hydrodynamics

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