Phase change memory, which is based on the reversible switching of phase change materials between amorphous and crystalline states, is one of the most promising bases of nonvolatile memory devices. However, the transition mechanism remains poorly understood. In this study, via in situ transmission electron microscopy with an externally applied DC voltage and nanosecond electrical pulses, for the first time we revealed a reversible structural evolution of Ge2Sb2Te5 thin films from an amorphous state to a single-crystal state via polycrystals as an intermediate state. This transition is different from the traditional understanding of structural changes in Ge2Sb2Te5, i.e., from an amorphous structure to a hexagonal close-packed structure via face-centered cubic as an intermediate structure. In situ observations indicate that this poly-to-single crystal structural transition is caused by coalescence of neighbouring grains induced by an electric field, in which a fast heating/cooling rate is found to be essential. Our study opens a new avenue for the realization of the multi-level operation of phase change materials.
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机译:基于相变材料在非晶态和结晶态之间可逆转换的相变存储器是非易失性存储设备最有希望的基础之一。但是,过渡机制仍然知之甚少。在这项研究中,通过使用外部施加的直流电压和纳秒电脉冲的原位透射电子显微镜,我们首次揭示了通过多晶作为中间产物,Ge2Sb2Te5薄膜从非晶态到单晶态的可逆结构演变。州。这种转变不同于传统上对Ge 2 Sb 2 Te 5中的结构变化的理解,即从无定形结构到以面心立方为中间结构的六方密堆积结构。原位观察表明,这种多晶到单晶的结构转变是由电场引起的相邻晶粒的聚结引起的,其中快速加热/冷却速率至关重要。我们的研究为实现相变材料的多级操作开辟了一条新途径。
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