Electromagnetic Vortices. Группа авторов

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Название Electromagnetic Vortices
Автор произведения Группа авторов
Жанр Физика
Серия
Издательство Физика
Год выпуска 0
isbn 9781119662877



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href="#ulink_e582bcdc-147e-5944-a36d-1f7688a56996">Figure 1.5. Note that the first term is frequency dependent similar to Eq. (1.10). The gradient of the wavefront (i.e. the wavevector direction) is:

      (1.12)nabla upper S Subscript italic upper L upper G Baseline equals k 0 ModifyingAbove r With ampersand c period circ semicolon plus ModifyingAbove phi With ampersand c period circ semicolon StartFraction l Over r sine theta EndFraction equals k 0 left-bracket ModifyingAbove r With ampersand c period circ semicolon plus ModifyingAbove phi With ampersand c period circ semicolon StartFraction l Over k 0 r sine theta EndFraction right-bracket period

      Unlike the wavevector of the Airy disk, the wavevector of a Laguerre–Gaussian beam has a radial and azimuthal component. Note that for very large distances compared to the wavelength (k0r → ∞),

      (1.13)nabla upper S Subscript italic upper L upper G Baseline almost-equals k 0 ModifyingAbove r With ampersand c period circ semicolon comma for k 0 r right-arrow infinity period

      In other words, the wavefront of a Laguerre–Gaussian modes at very large distances compared to the wavelength, i.e. in the very far‐field, resembles a spherical wavefront, as shown in Figure 1.5.

Schematic illustration of far-field wavefront of (a) Airy disk and (b, c) Laguerre–Gaussian modes. Schematic illustration of normalized directivities of the Airy disk pattern.

      The observation that OAM‐carrying beams exhibit two unique properties compared to conventional beams, namely, the orthogonality and divergence, gives rise to the following question: Can OAM beams’ unique characteristics potentially benefit communication links? We demonstrate that the answer is ‘yes,’ albeit there are still many challenges to overcome before OAM is employed in a practical application. Inspired by this question, we examine possible communication scenarios that involve OAM antennas, review potential applications of OAM beams in communication systems, and discuss technical challenges.

      1.3.1 OAM Communication Link Scenarios and Technical Barriers

      (1.14)StartFraction upper P Subscript upper R Baseline Over upper P Subscript upper T Baseline EndFraction equals left-parenthesis StartFraction normal lamda Over 4 normal pi d EndFraction right-parenthesis squared upper G Subscript upper T Baseline left-parenthesis theta Subscript t Baseline comma phi Subscript t Baseline right-parenthesis upper G Subscript upper R Baseline left-parenthesis theta Subscript r Baseline comma phi Subscript r Baseline right-parenthesis comma

      where PR and PT are the received and transmitted powers, respectively, λ is the operating wavelength, d represents the link distance, GT(θt, ϕt), GR(θr, ϕr) correspond to