Surface-plasmonic sensor using a columnar thin film in the grating-coupled configuration [Invited]

Kiran Mujeeb; Muhammad Faryad; Akhlesh Lakhtakia; Julio V. Urbina

doi:10.3788/COL202119.083601

Journals >Chinese Optics Letters >Volume 19 >Issue 8 >Page 083601 > Article

Chinese Optics Letters
Vol. 19, Issue 8, 083601 (2021)

Surface-plasmonic sensor using a columnar thin film in the grating-coupled configuration [Invited]

Kiran Mujeeb¹, Muhammad Faryad², Akhlesh Lakhtakia^3、*, and Julio V. Urbina⁴

Author Affiliations

¹Department of Electronics, Quaid-i-Azam University, Islamabad 45320, Pakistan

²Department of Physics, Lahore University of Management Sciences, Lahore 54792, Pakistan

³Department of Engineering Science and Mechanics, The Pennsylvania State University, University Park, Pennsylvania 16802, USA

⁴Department of Electrical Engineering, The Pennsylvania State University, University Park, Pennsylvania 16802, USA

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DOI: 10.3788/COL202119.083601 Cite this Article Set citation alerts

Kiran Mujeeb, Muhammad Faryad, Akhlesh Lakhtakia, Julio V. Urbina. Surface-plasmonic sensor using a columnar thin film in the grating-coupled configuration [Invited][J]. Chinese Optics Letters, 2021, 19(8): 083601 Copy Citation Text

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Schematic of the boundary-value problem solved for the surface-plasmonic sensor based on the grating-coupled configuration. The CTF is symbolically represented by a single row of nanocolumns, each of which is modeled as a string of electrically small ellipsoids with semi-axes in the ratio 1:γb:γτ.

Fig. 1. Schematic of the boundary-value problem solved for the surface-plasmonic sensor based on the grating-coupled configuration. The CTF is symbolically represented by a single row of nanocolumns, each of which is modeled as a string of electrically small ellipsoids with semi-axes in the ratio 1:γ_b:γ_τ.

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$(a) Real and (b) imaginary parts of q/k0 of the SPP wave propagating along the x axis as functions of the refractive index nL of the infiltrating fluid computed using solutions of the canonical boundary-value problem, whereas χv = 15 deg, γ = 30 deg, and εm = −15.4 + 0.4i, see Sections 3.1 and 3.2 for other relevant parameters.$

Fig. 2. (a) Real and (b) imaginary parts of q/k₀ of the SPP wave propagating along the x axis as functions of the refractive index n_L of the infiltrating fluid computed using solutions of the canonical boundary-value problem, whereas χ_v = 15 deg, γ = 30 deg, and ε_m = −15.4 + 0.4i, see Sections 3.1 and 3.2 for other relevant parameters.

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Fig. 3. Absorptance A_p as a function of incidence angle θ for L_c∈{1000, 2000, 3000, 4000} nm and L = 500 nm in the grating-coupled configuration. Whereas (a) n_L = 1, (b) n_L = 1.27, (c) n_L = 1.37, (d) n_L = 1.43, and (e), (f) n_L = 1.70, see Sections 3.1 and 3.3 for other relevant parameters. A downward arrow identifies the excitation of the SPP wave as a Floquet harmonic of order n, which is indicated alongside the arrow.

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Fig. 4. Absorptance A_p as a function of incidence angle θ when (a) n_L ∈ [1.00, 1.20], (b) n_L ∈ [1.21, 1.29], (c) n_L ∈ [1.30, 1.39], and (d) n_L ∈ [1.40, 1.50]. Whereas L_c = 3000 nm and L = 500 nm, see Sections 3.1 and 3.3 for other relevant parameters. The horizontal arrows show the direction of the shift of peaks representing the excitation of the SPP wave.

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$Sensitivity S as a function of the refractive index nL of the infiltrating fluid. The sensitivity, given by Eq. (10), was computed from the absorptance plots like the ones given in Fig. 4 with Lc = 3000 nm and L = 500 nm. Doublet excitation is possible for some ranges of nL in Fig. 5(c). The predicted sensitivity was computed using the solutions of the canonical problem in Re(q) = k0 sin θp + 2nπ/L to find predicted θp as a function of nL. All parameters were kept the same as for Fig. 4.$

Fig. 5. Sensitivity S as a function of the refractive index n_L of the infiltrating fluid. The sensitivity, given by Eq. (10), was computed from the absorptance plots like the ones given in Fig. 4 with L_c = 3000 nm and L = 500 nm. Doublet excitation is possible for some ranges of n_L in Fig. 5(c). The predicted sensitivity was computed using the solutions of the canonical problem in Re(q) = k₀ sin θ_p + 2nπ/L to find predicted θ_p as a function of n_L. All parameters were kept the same as for Fig. 4.

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$The angular location θp of an absorptance peak indicating the excitation of the SPP wave as a function of the refractive index nL ∈ [0.3, 2.5] of the infiltrating fluid. All parameters are the same as for Fig. 4. Triple excitation of the SPP wave occurs in the blue-shaded regions, double excitation in the gray-shaded regions, and single excitation in the green-shaded regions.$

Fig. 6. The angular location θ_p of an absorptance peak indicating the excitation of the SPP wave as a function of the refractive index n_L ∈ [0.3, 2.5] of the infiltrating fluid. All parameters are the same as for Fig. 4. Triple excitation of the SPP wave occurs in the blue-shaded regions, double excitation in the gray-shaded regions, and single excitation in the green-shaded regions.

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