Nonlocal Effective Medium (NLEM) for Quantitative Modelling of Nanoroughness in Spectroscopic Reflectance

Abstract: Spectroscopic reflectance is a versatile optical methodology for the characterization of transparent and semi-transparent thin films in terms of thickness and refractive index. The Fresnel equations are used to interpret the measurements, but their accuracy is limited when surface roughness is present. Nanoroughness can be modelled through a discretized multi-slice and effective medium approach, but to date, this offered mostly qualitative and not quantitative accuracy. Here we introduce an adaptive and nonloc… Show more

“…The absorbance data of figure 4(a) are truncated at UV = 300 nm, due to the cuvette absorbance ∼300 nm [161], making our n BP extraction qualitative, because of the finite integration range. We use the extracted BP refractive index in Fresnel equation calculations [162] to estimate the absorption of SLG/BP on Si/SiO 2 . The SLG refractive index is modelled by the Kubo conductance [163] at RT and E F = 0.38 eV, as estimated by the Raman measurements in figure 6.…”

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“…The absorbance data of figure 4(a) are truncated at UV = 300 nm, due to the cuvette absorbance ∼300 nm [161], making our n BP extraction qualitative, because of the finite integration range. We use the extracted BP refractive index in Fresnel equation calculations [162] to estimate the absorption of SLG/BP on Si/SiO 2 . The SLG refractive index is modelled by the Kubo conductance [163] at RT and E F = 0.38 eV, as estimated by the Raman measurements in figure 6.…”

Graphene-black phosphorus printed photodetectors