ZnS 纳米结构中热控循环插入/逐出掺杂离子和可逆闪锌矿/纤锌矿相转变。

Thermally controlled cyclic insertion/ejection of dopant ions and reversible zinc blende/wurtzite phase changes in ZnS nanostructures.

机构信息

Centre for Advanced Materials, Indian Association for the Cultivation of Science, Jadavpur, Kolkata 700032, India.

出版信息

J Am Chem Soc. 2011 Feb 16;133(6):1666-9. doi: 10.1021/ja109625v. Epub 2011 Jan 25.

Abstract

We report a reversible phase transformation of platelet-shaped ZnS nanostructures between wurtzite (WZ) and zinc blende (ZB) phases by reversible insertion/ejection of dopant Mn(II) ions induced by a thermocyclic process. In a reaction flask loaded with WZ ZnS platelets and Mn molecular precursors, during heating Mn ions are incorporated and change the phase of the host nanostructures to ZB; during cooling Mn ions are spontaneously ejected, returning the host nanoplatelets to the original WZ phase. These reversible changes are monitored for several cycles with PL, EPR, XRD, and HRTEM. Interestingly, the (0001) WZ platelets transform to (110) ZB following a nucleation and growth process triggered by a local increase/depletion of the Mn(2+) concentration in the nanocrystals.

摘要

我们报告了一种通过热循环过程可逆地插入/排出掺杂 Mn(II)离子来实现血小板状 ZnS 纳米结构在纤锌矿 (WZ)和闪锌矿 (ZB)相之间的可逆相转变。在一个装有 WZ ZnS 纳米板和 Mn 分子前体的反应瓶中，加热时 Mn 离子被掺入并改变了主体纳米结构的相为 ZB；冷却时 Mn 离子自发逸出，使主体纳米板恢复到原始的 WZ 相。通过 PL、EPR、XRD 和 HRTEM 对几个循环进行了可逆变化的监测。有趣的是，(0001)WZ 纳米板通过在纳米晶体中 Mn(2+)浓度的局部增加/耗尽触发的成核和生长过程转变为(110)ZB。

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ZnS 纳米结构中热控循环插入/逐出掺杂离子和可逆闪锌矿/纤锌矿相转变。

Thermally controlled cyclic insertion/ejection of dopant ions and reversible zinc blende/wurtzite phase changes in ZnS nanostructures.

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