Materials Research Centre, Indian Institute of Science , Bangalore-560012, India.
ACS Appl Mater Interfaces. 2017 May 17;9(19):16305-16312. doi: 10.1021/acsami.7b00587. Epub 2017 May 8.
Here, we report on the novel design of dual emission via defect state engineering in codoped oxide microstructures and its implication in fluorescence intensity ratio (FIR) based optical temperature sensing. Eu- and Er-co-doped ZnO (EuEr:ZnO) microrods prepared by hydrothermal method. The emission peaks corresponding to Eu and Er are observed suggesting dual emission from codoped ZnO. Interestingly, Er peak intensity decreases and that of Eu increases with increase of temperature as is the case of individual doped cases and dual emission is also achieved via phyical mixing of the individual doped ZnO. The opposite trend is due to the electron transfer from the defect levels of host ZnO to Eu and not to Er. Overall, our results pave the way in designing dual emission that can be exploited in FIR based temperature sensing. As an example, we probe temperature dependency of congo-red and polyvinyle alcohol (PVA) composite using EuEr:ZnO as optical probe for temperature sensing.
在这里,我们报告了通过共掺杂氧化物微结构中的缺陷态工程实现双发射的新颖设计及其在荧光强度比(FIR)基光学温度传感中的应用。通过水热法制备了 Eu 和 Er 共掺杂的 ZnO(EuEr:ZnO)微米棒。观察到对应于 Eu 和 Er 的发射峰,表明共掺杂 ZnO 的双发射。有趣的是,随着温度的升高,Er 峰强度降低,Eu 峰强度增加,这与单掺杂情况相同,并且通过单个掺杂 ZnO 的物理混合也实现了双发射。相反的趋势是由于电子从 ZnO 宿主的缺陷能级转移到 Eu 而不是 Er。总的来说,我们的结果为设计可以在基于 FIR 的温度传感中利用的双发射铺平了道路。例如,我们使用 EuEr:ZnO 作为光学探针,探测了刚果红和聚乙烯醇(PVA)复合材料的温度依赖性。
