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Article Abstract
Near-infrared (NIR) energy transfer upconversion (ETU) overcomes the photon energy limitations of single-photon processes via nonlinear optical effects, demonstrating unique advantages in deep material penetration and multielectron transfer. This work reports a high-efficiency photocatalytic system that synergizes NIR-driven ETU with CoO quantum dots (QDs). By integrating Er-doped upconversion nanoparticles (NaYF,Yb:Er) with CoO QD-modified g-CN nanosheets, we achieved energy conversion dominated by the ETU process under 980 nm NIR irradiation. Experimental power-dependent emission slopes of 2.23 (541 nm) and 1.89 (657 nm) confirm the underlying ETU mechanism, a typical two-photon-participating process. Yb sensitizers absorb NIR photons, transfer energy to Er for 4f-level transitions, and relay excited-state energy to the CoO/g-CN nanosheets heterojunction via Förster resonance energy transfer (FRET). The CoO QDs act as electron traps to enhance charge separation while activating O to generate superoxide radicals (O) and enabling hole-mediated oxidation, establishing a radical chain reaction pathway initiated by the ETU process. This system achieves challenging transformations under NIR, including benzyl C-H oxidation and thioether-specific conversions, successfully constructing omeprazole derivatives and 5-benzo[][1,4]-diazepine scaffolds. Compared to visible-light catalysts, it exhibits superior recyclability (>7 cycles), gram-scale capacity, and broad spectral response (200-1000 nm), offering a solar-driven strategy for green pharmaceutical synthesis. By decoupling photocatalysis from visible-light dependence through synergistic quantum dot interface engineering and an ETU-based strategy, this work advances NIR energy utilization in organic synthesis.
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| http://dx.doi.org/10.1021/acsami.5c07984 | DOI Listing |
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