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Cu(Ⅱ) detection is important because it plays crucial role in several biological processes and ecological systems.Fluorescent techniques have attracted more and more attention in Cu(Ⅱ) detection.In this report,we contribute a novel strategy to use fluorescence spectroscopy for Cu(Ⅱ) specific detection.The specificity relies on the fact that,of the many metal cations,only Cu(Ⅱ) can catalyze the hydrolyzation of a-amino acid ester.The novelty originates from the unique aggregation-induced emission(AIE) property of the fluorescent label.We designed a model a-amino acid ester(TPE-Ala) constructed with alanine and tetraphenylethene-functionalized methanol(TPE-methanol).In comparison with the precursor TPE-Ala, TPE-methanol has lower solubility and is easy to form aggregates in water,thereby displaying a higher fluorescent response.Thus,the Cu(Ⅱ) catalyzed hydrolyzation can be monitored by recording the fluorescence enhancement and fluorescent detection Cu(Ⅱ) is rationally achieved.
Cu (Ⅱ) detection is important because it plays crucial role in several biological processes and ecological systems. Fluorescent techniques have attracted more and more attention in Cu (Ⅱ) detection.In this report, we contribute a novel strategy to use fluorescence spectroscopy for Cu (Ⅱ) specific detection. The specificity relies on the fact that, of the many metal cations, only Cu (Ⅱ) can catalyze the hydrolyzation of a-amino acid ester. Novelty originates from the unique aggregation-induced emission (AIE) property of the fluorescent label. We designed a model a-amino acid ester (TPE-Ala) constructed with alanine and tetraphenylethene-functionalized methanol (TPE-methanol) .In comparison with the precursor TPE-Ala, TPE-methanol has lower solubility and is easy to form aggregates in water, displaying a higher fluorescent response. Here, the Cu (II) catalyzed hydrolyzation can be monitored by recording the fluorescence enhancement and fluorescent detection Cu (II) is rationally achievable ed.