Electron transport properties in tensile strained Si-based materials are theoretically
analyzed using Monte-Carlo calculation. We focus our interest on in-plane transport in
Si and Si1−yCy (y ≤ 0.03), grown respectively on 〈001〉
Si1−xGex pseudo-substrate and Si substrate, with a view to
Field-Effect-Transistor application. In comparison with unstrained Si, the tensile
strain effect is shown to be very attractive in Si: drift mobilities greater than
3000 cm2/Vs are obtained at 300 K for a Ge fraction mole of 0.2 in the
pseudo-substrate. In the Si1−yCy/Si system, that does not need any
pseudo-substrate, the beneficial strain effect on transport is counterbalanced by the
alloy scattering whose influence on mobility is studied. If the alloy potential is
greater than about 1 eV, the advantage of strain-induced reduction of effective mass
is lost in terms of stationary transport performance at 300 K.