2 research outputs found

    Widefield scanning imaging with optical super-resolution

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    <div><p>An economical, pollution-free microsphere-based widefield scanning imaging method is presented. This system is able to visualize the surface pattern of the sample through a transparent dielectric microsphere stuck onto a glass probe. The microsphere endows the system with super-resolution capability, while the field of view can easily be expanded by scanning and image stitching. The feasibilities and advantages of this method have been verified experimentally.</p></div

    Phase Control of Eu<sup>3+</sup>-Doped YPO<sub>4</sub> Nano-/Microcrystals

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    The crystal phase control is one of the most important issues in materials science, because different atomic arrangements and electronic structures of crystals will endow materials with enhanced or new functionalities. However, exploring a general rule to the phase control is extremely difficult, since the formation of new crystal phases is usually induced by many reaction parameters or methods. Here we describe a Eu<sup>3+</sup> (5 atom %)-doped YPO<sub>4</sub> nano-/microcrystal system in which the phase can be rationally tuned in hexagonal or tetragonal. We confirm that manipulating the relative concentrations of phosphate groups and free RE<sup>3+</sup> ions in using different approaches in the reaction solution can determine the formation of the final crystallographic phase of the Eu<sup>3+</sup>-doped YPO<sub>4</sub> nano-/microcrystals. Experimental observations show crystal structure offering powerful control over the morphologies and optical emission properties of the resulting nano-/microcrystals. We believe that the structural control scheme, demonstrated here in Eu<sup>3+</sup>-doped YPO<sub>4</sub> nano-/microcrystals, could be extended to other inorganic nano-/microcrystal systems for their desirable applications and their correlated fundamental research
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