Extension of an FFT-Based Beam Propagation Method to Plasmonic and Dielectric Waveguide Discontinuities and Junctions
Applied Sciences (Switzerland) • 2019
معلومات البحث
المؤلفون
Adel Shaaban, Yi-Chun Du, and Lotfy Rabeh Gomaa
الكلمات المفتاحية
Beam Propagation Method - Plasmonics - Junctions - Optical communications
المجلة العلمية
Applied Sciences (Switzerland)
الناشر
MDPI Multidisciplinary Digital Publishing Institute
المجلد
20
العدد
9
الصفحات
12
publication.type
International
رابط البحث
Open Link
المواد المرفقة
Not Available
الملخص
We adapted a fast Fourier transform-based Beam Propagation Method (FFT-BPM) to
investigate waveguide discontinuities in plasmonic waveguides. The adaptation of the FFT-BPM to
treat transverse magnetic (TM) fields requires the circumvention of two major difficulties: the mixed
derivatives of the magnetic field and waveguide refractive index profile in the TM wave equation and
the step-like index change at the transverse metal-dielectric boundary of the plasmonic guide and the
transverse boundaries of the dielectric waveguide as well. An equivalent-index method is adopted to
transform TM fields to transverse electric (TE) ones, thus enabling the benefit of the full power and
simplicity of the FFT-BPM. Moreover, an appropriate smoothing function is used to approximate
the step-like refractive index profile in the transverse direction. At the junction plane, we used an
accurate combined spatial-spectral reflection operator to calculate the reflected field. To validate
our proposed scheme, we investigated the modal propagation in a silicon waveguide terminated
by air (like a laser facet in two cases: with and without a coating layer). Then we considered a
subwavelength plasmonic waveguide (metal-insulator-metal MIM) butt-coupled with a dielectric
waveguide, where the power transmission efficiency has been calculated and compared with other
numerical methods. The comparison reveals good agreement.
investigate waveguide discontinuities in plasmonic waveguides. The adaptation of the FFT-BPM to
treat transverse magnetic (TM) fields requires the circumvention of two major difficulties: the mixed
derivatives of the magnetic field and waveguide refractive index profile in the TM wave equation and
the step-like index change at the transverse metal-dielectric boundary of the plasmonic guide and the
transverse boundaries of the dielectric waveguide as well. An equivalent-index method is adopted to
transform TM fields to transverse electric (TE) ones, thus enabling the benefit of the full power and
simplicity of the FFT-BPM. Moreover, an appropriate smoothing function is used to approximate
the step-like refractive index profile in the transverse direction. At the junction plane, we used an
accurate combined spatial-spectral reflection operator to calculate the reflected field. To validate
our proposed scheme, we investigated the modal propagation in a silicon waveguide terminated
by air (like a laser facet in two cases: with and without a coating layer). Then we considered a
subwavelength plasmonic waveguide (metal-insulator-metal MIM) butt-coupled with a dielectric
waveguide, where the power transmission efficiency has been calculated and compared with other
numerical methods. The comparison reveals good agreement.
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