The Sommerfeld half-space problem revisited: from radio frequencies and Zenneck waves to visible light and Fano modes

Michalski, Krzysztof A.; Mosig, J. R.

doi:10.1080/09205071.2015.1093964

Cited by 69 publications

(59 citation statements)

References 115 publications

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“…is a ubiquitous reference integral, which is usually expressed in terms of the complementary error function erfc [Bernard and Ishimaru, 1967;Felsen and Marcuvitz, 1973;Brekhovskikh, 1980]. In the above, as previously stated in Michalski and Mosig [2015b, 2015a, 2016a, we prefer to employ the related and well-researched…”

Section: Appendix A: Modified Saddle Point Methodsmentioning

confidence: 99%

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On the far‐zone electromagnetic field of a vertical Hertzian dipole over an imperfectly conducting half‐space with extensions to plasmonics

Michalski

Lin

2017

Radio Science

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New asymptotic formulas for the electromagnetic fields of a vertical Hertzian dipole over an imperfectly conducting half‐space are derived using two variants of the modified saddle point method, referred to as subtractive and multiplicative. The accuracy of the two far‐zone formulations is assessed by comparisons with the state‐of‐the‐art Norton‐Bannister theory and with the rigorous results of numerical integration for problems involving seawater in the microwave range and gold in the visible range. It is found that the performance of the three approximate methods is similar, except at the surface of plasmonic media, where the saddle point methods are superior to the Norton‐Bannister formulation.

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Section: Appendix A: Modified Saddle Point Methodsmentioning

confidence: 99%

“…where k 0 is the free-space wave number and A z is the z component of the magnetic vector potential, which may be expressed as [Collin, 2004;Michalski and Mosig, 2016a;Michalski and Nevels, 2017]…”

Section: Problem Statement and Formal Solutionmentioning

confidence: 99%

On the far‐zone electromagnetic field of a vertical Hertzian dipole over an imperfectly conducting half‐space with extensions to plasmonics

Michalski

Lin

2017

Radio Science

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“…VMD = vertical magnetic dipole; HMD = horizontal magnetic dipole. Electromagnetic (EM) waves propagation from Hertzian dipoles in the presence of isotropic layered media has been extensively investigated since the pioneering work by Sommerfeld in 1909(Sommerfeld, 1909, 1926 to the present time (Fei et al, 2007;Guzatov et al, 2013;Guzatov & Klimov, 2014;Liao & Sarabandi, 2007;Liu & Li, 2007;Long et al, 2001;Michalski & Mosig, 2016;Wang et al, 2014Wang et al, , 2015. As a result, the EM fields from a vertical magnetic dipole (VMD) or a horizontal magnetic dipole (HMD) in the presence of a two-layered or multilayered region have been presented in analytical closed-form expressions by many researchers, in particular, by Wait (1961Wait ( , 1996Wait ( , 1969Wait ( , 1972Wait ( , 1982.…”

Section: Radio Sciencementioning

confidence: 99%

A Computational Channel Model for Magnetic Induction‐Based Subsurface Applications

et al. 2019

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There are many underground applications based on magnetic fields generated by an oscillating magnetic source. For them, a magnetic dipole in a three‐layered region with upper semi‐infinite air layer can be a convenient idealization used for their planning, development, and operation. Solutions are in the form of the well‐known Sommerfeld integral expressions that can be evaluated by numerical methods. A set of field expressions to be numerically evaluated by an efficient algorithm are not collected comprehensively yet, or at least in a directly usable form. In this paper, the explicit magnetic field solutions for the vertical magnetic dipole and the horizontal magnetic dipole for a general source‐observer location are derived from the Hertz vector. They can be properly combined to model the problem of a tilted magnetic dipole source for horizontally or inclined stratified media. As a result, a complete set of integral equations of the Sommerfeld type valid from the near zone to the far zone are formulated. A method for numerical evaluation of the field expressions for high accurate computations is described. The numerical results are validated using the finite element method for all the possible source‐receiver configurations and three well‐spanned frequencies of typical subsurface applications. Both numerical solutions agree according to the normalized root‐mean‐square error‐based fit metric. Numerical results for two cases of study are presented to see its usefulness for subsurface applications. A MATLAB implementation of the mathematical description outlined in this paper and the proposed evaluation method is freely available for download.

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“…where k 0 is the free-space wave number and A = (̂cos −̂sin ) A x +ẑA z is the magnetic vector potential, with (Michalski & Mosig, 2016a)…”

Section: Problem Statement and Formal Solutionmentioning

confidence: 99%

“…as the "knee point" where the transition from  ( −1 ) to  ( −2 ) begins (Michalski & Mosig, 2016a). In the plasmonic case, when ℑs p > 0, the last term in the asymptotic expansion (A10) contributes…”

Section: 1002/2017rs006445mentioning

confidence: 99%

On the Far‐Zone Electromagnetic Field of a Horizontal Electric Dipole Over an Imperfectly Conducting Half‐Space With Extensions to Plasmonics

Michalski

Lin

2018

Radio Science

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Second‐order asymptotic formulas for the electromagnetic fields of a horizontal electric dipole over an imperfectly conducting half‐space are derived using the modified saddle‐point method. Application examples are presented for ordinary and plasmonic media, and the accuracy of the new formulation is assessed by comparisons with two alternative state‐of‐the‐art theories and with the rigorous results of numerical integration.

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The Sommerfeld half-space problem revisited: from radio frequencies and Zenneck waves to visible light and Fano modes

Cited by 69 publications

References 115 publications

On the far‐zone electromagnetic field of a vertical Hertzian dipole over an imperfectly conducting half‐space with extensions to plasmonics

On the far‐zone electromagnetic field of a vertical Hertzian dipole over an imperfectly conducting half‐space with extensions to plasmonics

A Computational Channel Model for Magnetic Induction‐Based Subsurface Applications

On the Far‐Zone Electromagnetic Field of a Horizontal Electric Dipole Over an Imperfectly Conducting Half‐Space With Extensions to Plasmonics

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