Dyakonov–Voigt surface waves

Mackay, Tom G.; Zhou, Chenzhang; Lakhtakia, Akhlesh

doi:10.1098/rspa.2019.0317

Cited by 36 publications

(34 citation statements)

References 27 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In order to characterize DV surface-wave propagation supported by dissipative materials, we now explore numerical solutions to the canonical boundary-value problem that satisfy the dispersion equation (24). In the special case considered previously [21], wherein the optic axis of material A lies in the interface plane (i.e., χ = 0 • ) and the materials A and B are nondissipative (and inactive), certain constraints on the relative permittivity parameters of materials A and B can be established. However, the general case (0 • ≤ χ ≤ 90 • and ε s A ∈ C, ε t A ∈ C, and ε B ∈ C) considered here is much less amenable to analysis and such constraints are not forthcoming.…”

Section: Numerical Studiesmentioning

confidence: 99%

On Dyakonov–Voigt surface waves guided by the planar interface of dissipative materials

2019

Self Cite

View full text Add to dashboard Cite

Dyakonov-Voigt (DV) surface waves guided by the planar interface of (i) material A which is a uniaxial dielectric material specified by a relative permittivity dyadic with eigenvalues ε s A and ε t A , and (ii) material B which is an isotropic dielectric material with relative permittivity ε B , were numerically investigated by solving the corresponding canonical boundary-value problem. The two partnering materials are generally dissipative, with the optic axis of material A being inclined at the angle χ ∈ [0 • , 90 • ] relative to the interface plane. No solutions of the dispersion equation for DV surface waves exist when χ = 90 • . Also, no solutions exist for χ ∈ (0 • , 90 • ), when both partnering materials are nondissipative. For χ ∈ [0 • , 90 • ), the degree of dissipation of material A has a profound effect on the phase speeds, propagation lengths, and penetration depths of the DV surface waves. For mid-range values of χ, DV surface waves with negative phase velocities were found. For fixed values of ε s A and ε t A in the upper-half-complex plane, DV surface-wave propagation is only possible for large values of χ when |ε B | is very small. *

show abstract

Section: Numerical Studiesmentioning

confidence: 99%

On Dyakonov–Voigt surface waves guided by the planar interface of dissipative materials

2019

Self Cite

View full text Add to dashboard Cite

show abstract

“…Then, has only two eigenvalues, namely , each with algebraic multiplicity 2 and geometric multiplicity 1 32 . Unlike the case when material is uniaxially dielectric 10 , there are two possible values of q that give rise to Dyakonov–Voigt surface waves, namely and ; from Eqs. ( 8 ), these are given as Herein the sign parameter for and for .…”

Section: Canonical Boundary-value Problemmentioning

confidence: 99%

“…Our analysis reveals that one or two Dyakonov–Voigt surface waves can be guided for each quadrant of the interface plane, depending upon the birefringence of partnering material . The manifestation of two Dyakonov–Voigt surface waves (rather than just one 13 ) marks a fundamental departure from the case involving the planar interface of a uniaxial dielectric material and an isotropic dielectric material 10 , 11 .…”

Section: Introductionmentioning

confidence: 99%

“…In addition to Dyakonov surface waves, it was recently discovered that the planar interface of a uniaxial dielectric material and an isotropic dielectric material can guide the propagation of Dyakonov-Voigt surface waves 10,11 . As compared to conventional surface waves such as surface-plasmon-polariton waves and Dyakonov surface waves, Dyakonov-Voigt surface waves have quite different localization characteristics.…”

mentioning

confidence: 99%

See 1 more Smart Citation

Two Dyakonov–Voigt surface waves guided by a biaxial–isotropic dielectric interface

Zhou

Mackay

Lakhtakia

2020

Sci Rep

Self Cite

View full text Add to dashboard Cite

Electromagnetic surface waves guided by the planar interface of an orthorhombic dielectric material and an isotropic dielectric material were analyzed theoretically and numerically. Both naturally occurring minerals (crocoite, tellurite, and cerussite) and engineered materials were considered as the orthorhombic partnering material. In addition to conventional Dyakonov surface waves, the analysis revealed that as many as two Dyakonov–Voigt surface waves can propagate in each quadrant of the interface plane, depending upon the birefringence of the orthorhombic partnering material. The coexistence of two Dyakonov–Voigt surface waves marks a fundamental departure from the corresponding case involving the planar interface of a uniaxial dielectric material and an isotropic dielectric material for which only one Dyakonov–Voigt surface wave is possible. The two Dyakonov–Voigt surface waves propagate in different directions in each quadrant of the interface plane, with different relative phase speeds and different penetration depths. Furthermore, the localization characteristics of the two Dyakonov–Voigt surface waves at the planar interface are quite different: the Dyakonov–Voigt surface wave with the higher relative phase speed is much less tightly localized at the interface in the isotropic dielectric partnering material.

show abstract

“…The surface waves are the electromagnetic waves which travel even with the speed of the light through a specified structure which contains both conductor and dielectric materials. [10][11][12][13][14] The surface wave phenomenon with the ability of interference reduction and power loss mitigation at millimeter range frequencies is proved to be the best alternate for the copper traces. [15][16][17][18] The channel model for the given application depicted in Figure 1 which performs data communication effectively based on suitable conditions of the proposed hybrid model.…”

Section: Introductionmentioning

confidence: 99%

Zenneck surface wave interconnect with encircle routing for effective inter chip communication

Penna

Shankar

Keshavamurthy

et al. 2021

Int J RF Microw Comput Aided Eng

View full text Add to dashboard Cite

Generally, copper traces are widely used to provide communication among integrated circuits (IC's) of printed circuit board (PCB). In case of high rate data transfer, systems or traces may be damaged due to trace resistivity. In order to overcome this issue, surface wave phenomenon based channel/ waveguide is introduced for IC communication in this work. Here, high frequency communication is possible due to both conductivity and dielectric behaviors of surface waves. Use of Zenneck surface instead of copper traces with Encircle Routing (ER) based channel assignment helps to achieve efficient IC communication. High rate of data transfer with low channel dispersion are major benefits of ER based Zenneck surface wave communication.Matlab working platform is used for design analysis by means of attenuation, field decay, skin depth, channel dispersion, power saving rate and signal voltage gain. Also, performance analysis is taken within the frequency range of 50 to 500 GHz to explore a deterministic channel communication between the IC's as an alternate of copper traces.

show abstract

Dyakonov–Voigt surface waves

Cited by 36 publications

References 27 publications

On Dyakonov–Voigt surface waves guided by the planar interface of dissipative materials

On Dyakonov–Voigt surface waves guided by the planar interface of dissipative materials

Two Dyakonov–Voigt surface waves guided by a biaxial–isotropic dielectric interface

Zenneck surface wave interconnect with encircle routing for effective inter chip communication

Contact Info

Product

Resources

About