Compound guided waves that mix characteristics of surface-plasmon-polariton, Tamm, Dyakonov–Tamm, and Uller–Zenneck waves

Francesco Chiadini; Vincenzo Fiumara; Antonio Scaglione; Akhlesh Lakhtakia

doi:10.1364/JOSAB.33.001197

Journal of the Optical Society of America B
Vol. 33,
Issue 6,
pp. 1197-1206
(2016)
•https://doi.org/10.1364/JOSAB.33.001197

Compound guided waves that mix characteristics of surface-plasmon-polariton, Tamm, Dyakonov–Tamm, and Uller–Zenneck waves

Francesco Chiadini, Vincenzo Fiumara, Antonio Scaglione, and Akhlesh Lakhtakia

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Francesco Chiadini, Vincenzo Fiumara, Antonio Scaglione, and Akhlesh Lakhtakia, "Compound guided waves that mix characteristics of surface-plasmon-polariton, Tamm, Dyakonov–Tamm, and Uller–Zenneck waves," J. Opt. Soc. Am. B 33, 1197-1206 (2016)

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Abstract

Solutions of the boundary-value problem for electromagnetic waves guided by a layer of a homogeneous and isotropic (metal or dielectric) material sandwiched between a structurally chiral material (SCM) and a periodically multilayered isotropic dielectric (PMLID) material were numerically obtained and analyzed. If the sandwiched layer is sufficiently thick, the two bimaterial interfaces decouple from each other, and each interface may guide one or more electromagnetic surface waves (ESWs) by itself. Depending on the constitution of the two materials that partner to form an interface, the ESWs can be classified as surface-plasmon-polariton waves, Tamm waves, Dyakonov–Tamm waves, or Uller–Zenneck waves. When the sandwiched layer is sufficiently thin, the ESWs for single bimaterial interfaces coalesce to form compound guided waves (CGWs). The phase speeds, propagation distances, and spatial profiles of the electromagnetic fields of CGWs are different from those of the ESWs. The energy of a CGW is distributed in both the SCM and the PMLID material, if the sandwiched layer is sufficiently thin. Some CGWs require the sandwiched layer to have a minimum thickness. Indeed, the coupling between the two faces of the sandwiched layer is affected by the ratio of the thickness of the sandwiched layer to the skin depth in that material and the rates at which the fields of the ESWs guided individually by the two interfaces decay away from their respective guiding interfaces.

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$j$	${SiO}_{2} %$	${SiN}_{x} %$	$ϵ_{j}$
1	0	100	3.9357
2	32	68	3.3033
3	40	60	3.1515
4	49	51	3.0056
5	62	38	2.7526
6	72	28	2.6143
7	82	18	2.4475
8	90	10	2.3161
9	100	0	2.1837

	Partnering Materials
ESW Type	A	B	Data	Number of Modes	Characteristics
SPP	SCM	Metal	Table 3	2	No polarization state can be assigned
	PMLID material	Metal	Table 5	7	4 $p$ - and 3 $s$ -polarized, 2 high-phase-speed solutions
Uller–Zenneck	SCM	Dissipative HID	Table 4	2	No polarization state can be assigned
	PMLID material	Dissipative HID	Table 6	6	3 $p$ - and 3 $s$ -polarized, 2 high-phase-speed solutions
Tamm	SCM	Nondissipative HID	–	0	–
	PMLID material	Nondissipative HID	Table 7	2	1 $p$ - and 1 $s$ -polarized
Dyakonov–Tamm	SCM	PMLID material	–	1	No polarization state can be assigned

Solution	$Re (\tilde{q})$	$Im (\tilde{q})$	$v_{ph} / c_{0}$	$Δ_{prop}$ (μm)
1	1.18553	$3.48 \times 10^{- 3}$	0.84350	28.95
2	1.85217	$1.77 \times 10^{- 2}$	0.53991	5.69

Solution	$Re (\tilde{q})$	$Im (\tilde{q})$	$v_{ph} / c_{0}$	$Δ_{prop}$ (μm)
1	1.06817	$5.90 \times 10^{- 2}$	0.93618	1.71
2	1.52148	$5.58 \times 10^{- 2}$	0.65725	1.81

Solution	$Re (\tilde{q})$	$Im (\tilde{q})$	$v_{ph} / c_{0}$	$Δ_{prop}$ (μm)
$p_{1}$	0.93964	$5.21 \times 10^{- 4}$	$1.06424$	193.37
$p_{2}$	1.36469	$1.56 \times 10^{- 4}$	0.73277	645.80
$p_{3}$	1.59093	$1.49 \times 10^{- 3}$	0.62856	67.61
$p_{4}$	2.27526	$3.81 \times 10^{- 2}$	0.43951	2.64
$s_{1}$	0.95783	$1.26 \times 10^{- 3}$	1.04403	79.96
$s_{2}$	1.40658	$8.45 \times 10^{- 4}$	0.71094	119.22
$s_{3}$	1.66592	$7.57 \times 10^{- 4}$	0.60027	133.08

Solution	$\tilde{q}$	$v_{ph} / c_{0}$
$p_{1}$	1.72282	0.58044
$s_{1}$	1.74660	0.57254

Solution	$Re {\tilde{q}}$	$Im {\tilde{q}}$	$v_{ph} / c_{0} 0$	$Δ_{prop}$ (μm)	$L_{th}$ (nm)
1	0.93964	$5.19 \times 10^{- 4}$	1.06424	194.11	46
2	0.95784	$1.25 \times 10^{- 3}$	1.04402	80.60	42
3	1.18554	$3.48 \times 10^{- 3}$	0.84350	28.95	46
4	1.36469	$1.56 \times 10^{- 4}$	0.73277	645.80	42
5	1.40658	$8.44 \times 10^{- 4}$	0.71094	119.37	36
6	1.59093	$1.48 \times 10^{- 3}$	0.62856	68.07	46
7	1.66592	$7.57 \times 10^{- 4}$	0.60027	133.08	18
8	1.85214	$1.77 \times 10^{- 2}$	0.53992	5.69	0
9	2.27538	$3.81 \times 10^{- 2}$	0.43949	2.64	$< 21$

Solution	$Re {\tilde{q}}$	$Im {\tilde{q}}$	$v_{ph} / c_{0} 0$	$Δ_{prop}$ (μm)
$a$	0.91803	$6.06 \times 10^{- 2}$	1.08929	1.66
$b$	0.92057	$3.97 \times 10^{- 2}$	1.08663	2.54
$c$	1.06833	$5.90 \times 10^{- 2}$	$0.93604$	1.71
$d$	1.38090	$3.14 \times 10^{- 2}$	$0.72417$	3.21
$e$	1.51980	$5.85 \times 10^{- 2}$	$0.65798$	1.72
$f$	1.52934	$5.27 \times 10^{- 2}$	$0.65388$	1.91
$g$	1.64373	$2.68 \times 10^{- 2}$	$0.60837$	3.76
$h$	1.71959	$1.44 \times 10^{- 1}$	$0.58153$	0.70

Solution	$Re {\tilde{q}}$	$Im {\tilde{q}}$	$v_{ph} / c_{0} 0$	$Δ_{prop}$ (μm)
$a$	0.91803	$6.06 \times 10^{- 2}$	1.08929	1.66
$b$	0.92057	$3.97 \times 10^{- 2}$	1.08663	2.54
$c$	1.06833	$5.90 \times 10^{- 2}$	$0.93604$	1.71
$d$	1.38090	$3.14 \times 10^{- 2}$	$0.72417$	3.21
$e$	1.51980	$5.85 \times 10^{- 2}$	$0.65798$	1.72
$f$	1.52934	$5.27 \times 10^{- 2}$	$0.65388$	1.91
$g$	1.64373	$2.68 \times 10^{- 2}$	$0.60837$	3.76
$h$	1.71959	$1.44 \times 10^{- 1}$	$0.58153$	0.70

Abstract

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Figures (13)

Tables (10)

Equations (11)

Journal of the Optical Society of America B