Wahid Sumaiya, Daus Alwin, Chen Victoria, Pop Eric
Department of Electrical Engineering, Stanford University, Stanford, California 94305, United States.
Department of Microsystems Engineering (IMTEK), University of Freiburg, 79110 Freiburg, Germany.
ACS Appl Mater Interfaces. 2024 Aug 14;16(32):42476-42480. doi: 10.1021/acsami.4c07793. Epub 2024 Aug 1.
We present a new approach to achieve nanoscale transistors on ultrathin flexible substrates with conventional electron-beam lithography. Full devices are first fabricated on a gold sacrificial layer covering a rigid silicon substrate, and then coated with a polyimide film and released from the rigid substrate. This approach bypasses nanofabrication constraints on flexible substrates: (i) electron-beam surface charging, (ii) alignment inaccuracy due to the wavy substrate, and (iii) restricted thermal budgets. As a proof-of-concept, we demonstrate ∼100 nm long indium tin oxide (ITO) transistors on ∼6 μm thin polyimide. This is achieved with sub-20 nm misalignment or overlap between source (or drain) and gate contacts on flexible substrates for the first time. The estimated transit frequency of our well-aligned devices can be up to 3.3 GHz, which can be further improved by optimizing the device structure and performance.
我们提出了一种利用传统电子束光刻技术在超薄柔性衬底上制备纳米级晶体管的新方法。首先在覆盖刚性硅衬底的金牺牲层上制造完整的器件,然后用聚酰亚胺薄膜进行涂覆,并从刚性衬底上释放出来。这种方法绕过了柔性衬底上的纳米制造限制:(i)电子束表面充电,(ii)由于衬底呈波浪状导致的对准不准确,以及(iii)有限的热预算。作为概念验证,我们展示了在约6μm厚的聚酰亚胺上制备的约100nm长的氧化铟锡(ITO)晶体管。首次在柔性衬底上实现了源极(或漏极)与栅极接触之间小于20nm的对准偏差或重叠。我们对准良好的器件估计的渡越频率可达3.3GHz,通过优化器件结构和性能可进一步提高。
