This review discusses critical aspects of patterning phase change materials (PCMs), including dry etching, wet clean, and encapsulation, as they dictate the reliability and functionality of the phase change random access memory devices. Specifically, alloys of germanium–antimony–tellurium are used as a model system, and the importance of PCM composition control, critical dimension control, high fidelity pattern transfer, and a system level of ambient control to avoid oxidation that can alter the materials’ functionality are highlighted. The research findings motivate the development of a state-of-the-art integrated system that combines dry etch, wet clean, and encapsulation into one platform to realize consistent and successful patterning of PCMs for future generations of the memory devices.
Phase change materials (PCM) have emerged as the leading candidate for next generation non-volatile storage class memory as demonstrated by the commercialization of 3D Cross Point memory. More recently, PCM memories have been explored for non-von Neumann system architectures with potential applications in neuromorphic computing. To accelerate the widespread adoption of PCM technology, better understanding of the unit processes and its interactions is needed to cost effectively produce high fidelity PCM devices. Challenges in creating cross point PCM architectures are significantly different from more dominant technologies such as DRAM and 3DNAND. From a device perspective, the PCM composition is sensitive to crystallization temperature, which translates to potentially large changes in the switching resistance for small changes in composition. From a material perspective, phase change chalcogenides readily etch in various plasma etch chemistries with the many etch chemistries exhibiting bulk composition changes. Furthermore, slight changes in the PCM composition can be removed by wet clean. In this regard, one of the main process challenges is to not etch chalcogenides laterally in order to maximizing the device volume. Finally, from a structural perspective, PCM are relatively soft with Young’s modulus that can be 3x smaller than materials found in DRAM/3DNAND stacks (e.g. Si, SiOx). Soft chalcogenides can lead to increased line bending, especially when the chalcogenide is at the bottom of the stack. As a result, post wet clean pattern collapse and line bending from film stress can be challenging to manage. To meet the material and structural challenges, we developed an integrated system combining dry etch, wet clean, and deposition process modules. Comprehensive understanding of each process module as well as the interactions of different process modules has been obtained. We will present some holistic process solutions combining dry etch, wet clean, and deposition to deliver collapse free, high fidelity PCM structures.
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