Luminescent ZnO-Carbon Hybrid Nanomaterials: Synthesis, Characterization, Emission Mechanism, and Applications

ACS Applied Optical Materials Pub Date : 2025-02-26 DOI:10.1021/acsaom.4c0050910.1021/acsaom.4c00509

Benjamin Sreenan*, Vala Kafil, Tanner Hunt, Sun Hae Ra Shin, Alec A. Brennan, Praveen K. Thallapally, Yftah Tal-Gan and Xiaoshan Zhu*,

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Abstract

In this study, hybrid zinc-oxide–carbon nanomaterials (ZnO–C-NMs) with 2–5 nm ZnO nanoparticles embedded in a C nanomatrix were developed through a facile one-pot solvothermal synthesis method. Under UV excitation (355 nm), ZnO–C-NMs emit weak blue luminescence, but under visible light excitation (405 nm), they present a bright green emission. Such luminescence properties are much different from those of C-NMs (synthesized under the same conditions as ZnO–C-NMs, except without the addition of Zn precursors). Through optical characterization and comparison of these materials, the luminescence mechanism of ZnO–C-NMs was discussed; the unique luminescence properties can be attributed to the interaction between the electronic structures of the ZnO nanoparticles and the C matrix. It was also found that ZnO–C-NMs possess excellent luminescence stability in water even under harsh conditions (e.g., high salinity, high concentrations of reactive oxygen species, or wide pH ranges). The observed phenomena may be rooted in a hydration layer on the surface of ZnO–C-NMs through the electrostatic absorption of water molecules. Based on their physiochemical merits, ZnO–C-NMs were successfully employed to detect trace amounts of water in commonly used low-polarity organic solvents with high sensitivities. We believe that such hybrid ZnO–C-NMs have potential for broader applications in sensing, imaging, photocatalysis, and others due to their unique luminescence properties or electronic structures.

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发光zno -碳杂化纳米材料：合成、表征、发射机理及应用

在本研究中，通过简单的一锅溶剂热合成方法，在C纳米基质中包埋2-5 nm ZnO纳米颗粒，制备了ZnO - C- nms杂化氧化锌-碳纳米材料（ZnO - C- nms）。在紫外光（355nm）激发下，ZnO-C-NMs发出微弱的蓝色发光，而在可见光（405 nm）激发下，ZnO-C-NMs发出明亮的绿色发光。这种发光性能与C-NMs（在与ZnO-C-NMs相同的条件下合成，除了没有添加Zn前驱体）有很大的不同。通过对这些材料的光学表征和比较，讨论了ZnO-C-NMs的发光机理；这种独特的发光特性可归因于ZnO纳米粒子的电子结构与C基体之间的相互作用。研究还发现，ZnO-C-NMs在水中具有优异的发光稳定性，即使在恶劣的条件下（例如，高盐度、高浓度活性氧或宽pH范围）。所观察到的现象可能是由于ZnO-C-NMs表面的水化层通过水分子的静电吸收而产生的。基于ZnO-C-NMs的理化特性，成功地将其应用于常用低极性有机溶剂中痕量水的检测，具有较高的灵敏度。我们相信这种混合ZnO-C-NMs由于其独特的发光性质或电子结构，在传感、成像、光催化等方面具有更广泛的应用潜力。

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来源期刊

ACS Applied Optical Materials 材料科学-光学材料-

CiteScore

1.10

自引率

0.00%

发文量

期刊介绍： ACS Applied Optical Materials is an international and interdisciplinary forum to publish original experimental and theoretical including simulation and modeling research in optical materials complementing the ACS Applied Materials portfolio. With a focus on innovative applications ACS Applied Optical Materials also complements and expands the scope of existing ACS publications that focus on fundamental aspects of the interaction between light and matter in materials science including ACS Photonics Macromolecules Journal of Physical Chemistry C ACS Nano and Nano Letters.The scope of ACS Applied Optical Materials includes high quality research of an applied nature that integrates knowledge in materials science chemistry physics optical science and engineering.