Kumaar Dhananjeya, Can Matthias, Weigand Helena, Yarema Olesya, Wintersteller Simon, Grange Rachel, Wood Vanessa, Yarema Maksym
Chemistry and Materials Design, Institute for Electronics, Department of Information Technology and Electrical Engineering, ETH Zürich, 8092 Zürich, Switzerland.
Optical Nanomaterial Group, Institute for Quantum Electronics, Department of Physics, ETH Zürich, 8093 Zürich, Switzerland.
Chem Mater. 2024 Jun 24;36(13):6598-6607. doi: 10.1021/acs.chemmater.4c01009. eCollection 2024 Jul 9.
Phase-change memory (PCM) technology has recently attracted a vivid interest for neuromorphic applications, in-memory computing, and photonic integration due to the tunable refractive index and electrical conductivity between the amorphous and crystalline material states. Despite this, it is increasingly challenging to scale down the device dimensions of conventionally sputtered PCM memory arrays, restricting the implementation of PCM technology in mass applications such as consumer electronics. Here, we report the synthesis and structural study of sub-10 nm Cu-Ge-Te (CGT) nanoparticles as suitable candidates for low-cost and ultrasmall PCM devices. We show that our synthesis approach can accurately control the structure of the CGT colloids, such as composition-tuned CGT amorphous nanoparticles as well as crystalline CGT nanoparticles with trigonal α-GeTe and tetragonal CuGeTe phases. In situ characterization techniques such as high-temperature X-ray diffraction and X-ray absorption spectroscopy reveal that Cu doping in GeTe improves the thermal properties and amorphous phase stability of the nanoparticles, in addition to nanoscale effects, which enhance the nonvolatility characteristics of CGT nanoparticles even further. Moreover, we demonstrate the thin-film fabrication of CGT nanoparticles and characterize their optical properties with spectroscopic ellipsometry measurements. We reveal that CGT nanoparticle thin films exhibit a negative reflectivity change and have good reflectivity contrast in the near-IR spectrum. Our work promotes the possibility to use PCM in nanoparticle form for applications such as electro-optical switching devices, metalenses, reflectivity displays, and phase-change IR devices.
相变存储器(PCM)技术最近因非晶态和晶态材料状态之间可调的折射率和电导率,在神经形态应用、内存计算和光子集成方面引起了广泛关注。尽管如此,按比例缩小传统溅射PCM存储器阵列的器件尺寸变得越来越具有挑战性,这限制了PCM技术在消费电子等大规模应用中的实现。在此,我们报告了亚10纳米铜锗碲(CGT)纳米颗粒的合成及结构研究,它们是低成本和超小型PCM器件的合适候选材料。我们表明,我们的合成方法可以精确控制CGT胶体的结构,例如成分可调的CGT非晶纳米颗粒以及具有三角α-GeTe和四方CuGeTe相的晶态CGT纳米颗粒。高温X射线衍射和X射线吸收光谱等原位表征技术表明,在GeTe中掺杂铜除了产生纳米尺度效应外,还改善了纳米颗粒的热性能和非晶相稳定性,进一步增强了CGT纳米颗粒的非易失性特性。此外,我们展示了CGT纳米颗粒的薄膜制备,并通过光谱椭偏测量对其光学性质进行了表征。我们发现CGT纳米颗粒薄膜表现出负反射率变化,并且在近红外光谱中具有良好的反射率对比度。我们的工作推动了将纳米颗粒形式的PCM用于电光开关器件、超颖透镜、反射率显示器和相变红外器件等应用的可能性。
