Chemistry publications

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Browsing Chemistry publications by Author "Acosta, L.K."

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    Enhancing forbidden light propagation in nanoporous anodic alumina gradient-index filters by alcohol additives
    (American Chemical Society (ACS), 2020) Lim, S.Y.; Law, C.S.; Jiang, L.; Acosta, L.K.; Bachhuka, A.; Marsal, L.F.; Abell, A.D.; Santos, A.
    A comprehensive study on structural and optical engineering of high-quality nanoporous anodic alumina gradient-index filters (NAA-GIFs) by selective addition of alcohols to the anodizing acid electrolyte is presented. Analysis of the combined effect of type (methanol, ethanol, isopropanol, and ethylene glycol) and concentration (from 10 to 70 vol %) of alcohol additives in sulfuric acid electrolytes on the optical features of the characteristic photonic stopband of NAA-GIFs—central wavelength, full width at half maximum, intensity, and quality factor—allows us to elucidate the most optimal fabrication conditions to produce high-quality NAA-GIFs by sinusoidal pulse anodization under mild conditions. Comprehensive electrochemical, structural, optical, and chemical analyses demonstrate that a suitable selection of type and concentration of the alcohol additive is critical in controlling the quality of forbidden light propagation within these photonic crystal (PC) structures. Particularly, NAA-GIFs produced by sinusoidal pulse anodization in the sulfuric acid electrolyte modified with 40 vol % methanol achieve an outstanding quality factor of ∼58 (32–54% superior than that of other alcohol additives). Our findings indicate that a combination of anodic oxide growth rate and suppressing dissolution efficiencies, mildly branched nanoporous structure, and incorporation of carbon-containing impurities into the structure of NAA-GIFs are critical factors in enhancing light-forbidding quality of these NAA-based PCs. Our results advance the understanding of structural engineering of NAA-PCs by dynamic modification of the input anodization profile under optimal electrolyte conditions.
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    Role of spectral resonance features and surface chemistry in the optical sensitivity of light-confining nanoporous photonic crystals
    (American Chemical Society, 2021) Acosta, L.K.; Law, S.; Lim, S.Y.; Abell, A.D.; Marsal, L.F.; Santos, A.
    Nanoporous anodic alumina optical microcavities (NAA-μQVs) with spectrally tunable resonance band and surface chemistry are used as model light-confining photonic crystal (PC) platforms to elucidate the combined effect of spectral light confinement features and surface chemistry on optical sensitivity. These model nanoporous PCs show well-resolved, spectrally tunable resonance bands (RBs), the central wavelength of which is engineered from ∼400 to 800 nm by the period of the input anodization profile. The optical sensitivity of the as-produced (hydrophilic) and dichlorodimethylsilane-functionalized (hydrophobic) NAA-μQVs is studied by monitoring dynamic spectral shifts of their RB upon infiltration with organic- and aqueous-based analytical solutions of equally varying refractive index, from 1.333 to 1.345 RIU. Our findings demonstrate that hydrophilic NAA-μQVs show ∼81 and 35% superior sensitivity to their hydrophobic counterparts for organic- and aqueous-based analytical solutions, respectively. Interestingly, the sensitivity of hydrophilic NAA-μQVs per unit of spectral shift is more than 3-fold higher in organic than in aqueous matrices upon equal change of refractive index, with values of 0.347 ± 0.002 and 0.109 ± 0.001 (nm RIU-1) nm-1, respectively. Conversely, hydrophobic NAA-μQVs are found to be slightly more sensitive toward changes of refractive index in aqueous medium, with sensitivities of 0.072 ± 0.002 and 0.066 ± 0.006 (nm RIU-1) nm-1 in water- and organic-based analytical solutions, respectively. Our advances provide insights into critical factors determining optical sensitivity in light-confining nanoporous PC structures, with implications across optical sensing applications, and other photonic technologies.