Chemical mechanical planarization for Ta-based superconducting quantum devices

Bhatia, Ekta, Kar, Soumen, Nalaskowski, Jakub, Vo, Tuan, Olson, Stephen, Frost, Hunter, Mucci, John, Martinick, Brian, Hung, Pui Yee, Wells, Ilyssa, Schujman, Sandra, Rao, Satyavolu S. Papa
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引用次数: 1

Abstract

We report on the development of a chemical mechanical planarization (CMP) process for thick damascene Ta structures with pattern feature sizes down to 100 nm. This CMP process is the core of the fabrication sequence for scalable superconducting integrated circuits at a 300 mm wafer scale. This work has established the elements of various CMP-related design rules that can be followed by a designer for the layout of circuits that include Ta-based coplanar waveguide resonators, capacitors, and interconnects for tantalum-based qubits and single flux quantum circuits. The fabrication of these structures utilizes a 193 nm optical lithography along with 300 mm process tools for dielectric deposition, reactive ion etch, wet-clean, CMP, and in-line metrology—all tools typical for a 300 mm wafer CMOS foundry. Theprocess development was guided by measurements of the physical and electrical characteristics of the planarized structures. Physical characterization such as atomic force microscopy across the 300 mm wafer surface showed that local topography was less than 5 nm. Electrical characterization confirmed low leakage at room temperature, and less than 12% within wafer sheet resistance variation for damascene Ta line widths ranging from 100 nm to 3 μm. Run-to-run reproducibility was also evaluated. Effects of process integration choices including the deposited thickness of Ta are discussed.
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基于ta的超导量子器件的化学机械平面化
我们报道了一种化学机械平面化(CMP)工艺的发展,用于图案特征尺寸低至100 nm的厚的大马士革Ta结构。该CMP工艺是300毫米晶圆级可扩展超导集成电路制造流程的核心。这项工作已经建立了各种cmp相关设计规则的元素,设计人员可以遵循这些规则来设计电路布局,包括基于钽的共面波导谐振器、电容器和基于钽的量子比特和单通量量子电路的互连。这些结构的制造采用193nm光学光刻以及300mm工艺工具,用于介质沉积,反应离子蚀刻,湿式清洁,CMP和在线计量-所有这些工具都是300mm晶圆CMOS代工厂的典型工具。该工艺开发是通过测量平面结构的物理和电气特性来指导的。原子力显微镜等物理表征表明,300 mm晶圆表面的局部形貌小于5 nm。电学特性证实,在室温下漏电率较低,在100 nm至3 μm的damascene Ta线宽度范围内,在晶片电阻变化范围内漏电率小于12%。还评估了运行到运行的重复性。讨论了工艺集成选择的影响,包括Ta的沉积厚度。
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