Pulsed laser annealing for advanced performance of mechanically flexible and optically transparent multilayer MoS2 transistors (Presentation Recording)

Hyuk‐Jun Kwon, Woong Choi, M. Oh, Sunkook Kim, C. Grigoropoulos
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Abstract

Laser enables the achievement of superb interfacial characteristics between electrode and semiconducting material contact surface and is also useful for a reduction in contact resistance. The irradiation of a pulsed laser with high energy density and short wavelength onto the electrodes leads to thermal annealing at the locally confined small area that needs high temperature without inflicting thermal damage. This contrasts conventional thermal annealing that affects the entire panel, including unwanted areas in which the annealing process should be excluded. We demonstrate that mechanically flexible and optically transparent (more than 81% transmittance in visible wavelength) multilayered molybdenum disulfide (MoS2) thin-film transistors (TFTs) in which the source/drain electrodes are selectively annealed using picosecond laser achieve the enhancement of device performance without plastic deformation, such as higher mobility, increased output resistance, and decreased subthreshold swing. Numerical thermal simulation for the temperature distribution, transmission electron microscopy (TEM) analysis, current-voltage measurements, and contact-free mobility extracted from the Y-function method (YFM) enable understanding of the compatibility and the effects of pulsed laser annealing process; the enhanced performance originated not only from a decrease in the Schottky barrier effect at the contact, but also an improvement of the channel interface. Furthermore, these results show that the laser annealing can be a promising technology to build up a high performance transparent and flexible electronics.
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机械柔性、光学透明多层MoS2晶体管的脉冲激光退火技术(演示记录)
激光使电极和半导体材料接触面之间实现了极好的界面特性,也有助于减少接触电阻。高能量密度和短波长的脉冲激光照射到电极上,可以在需要高温的局部受限小区域进行热退火,而不会造成热损伤。这与影响整个面板的传统热退火形成对比,包括退火过程应排除的不需要的区域。我们证明了机械柔性和光学透明(在可见波长透射率超过81%)的多层二硫化钼(MoS2)薄膜晶体管(TFTs),其中源极/漏极使用皮秒激光选择性退火,实现了器件性能的增强,而没有塑性变形,例如更高的迁移率,增加的输出电阻和减少的亚阈值摆动。温度分布的数值热模拟,透射电子显微镜(TEM)分析,电流-电压测量,以及从y函数法(YFM)提取的无接触迁移率,使人们能够理解脉冲激光退火过程的兼容性和影响;性能的提高不仅源于接触处肖特基势垒效应的减小,还源于通道界面的改善。此外,这些结果表明,激光退火是一种有前途的技术,可以建立一个高性能的透明和柔性电子。
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