The effects of strain on carrier transport in thin and ultra-thin SOI MOSFETs

Thin-body MOSFET geometries such as fully-depleted SO1 and double-gate devices are attractive because they can offer superior scaling properties compared to bulk and thick-body SO1 devices. The electrostatics of a MOSFET limit how short of a gate length can be achieved before the gate loses control over the channel. In bulk-like devices, the device designer keeps the gate in control with gate oxide scaling and doping profile design. In thin-body geometries, silicon thickness is a new, powerful scaling parameter. Much like with gate oxide scaling, the electrostatics improve with thinner films. This means that the limits of scaling thin-body devices are closely tied with the limits of scaling silicon film thickness. Electrical transport appears to be one of the limiting factors for scaling body thickness. As the silicon film thickness is reduced into the ultra-thin regime, where the film is thinner than the bulk inversion layer thickness, quantum confinement effects begin to be observed. For the most part, these effects act to degrade mobility, reducing performance and making further scaling less rewarding. This work focuses on finding methods to maintain good mobility in ultra-thin silicon films. Thin and ultra-thin body relaxed SO1 and biaxially strained SO1 MOSFETs were constructed and measured with and without the application of mechanical uniaxial strain to examine the interaction between strain and thin-film effects. The band splitting induced by the application of strain is found to at least partially mitigate the mechanisms responsible for degrading electron mobility in ultra-thin films. Additionally, the enhancement seen with uniaxial strain is found to further enhance mobility in biaxially strained films. Finally, the effective mass change caused by uniaxial strain is found to cause the mobility modulation to have a directional dependence, especially in already biaxially strained films. Thesis Supervisor: Dimitri A. Antoniadis Title: Ray and Maria Stata Professor of Electrical Engineering