A.V. Pozdneev, Valéry Weber, et al.
SC 2016
A multiscale method is proposed to analyze the internal redistribution of tensile strain applied to silicon 〈 100 〉 nanowires and its effect on electron effective masses m. Nonperiodic, realistic models of unprecedented size containing up to 2.2× 107 atoms (652×26×26 nm 3) allow the identification of nonuniform redistribution patterns specific to the constraints applied to impose external strain. Depending on how the external strain is imposed, silicon nanowires can show m behavior similar to strained bulk silicon, or, as a function of nanowire size, can display intrinsic strain large enough that external strain hardly reduces m further. For nanowire cross section sizes smaller than 8×8 nm2 quantum confinement leads to an increase in m which cannot be compensated for by tensile strain. © 2010 American Institute of Physics.
A.V. Pozdneev, Valéry Weber, et al.
SC 2016
Johann Rudi, Cristiano Malossi, et al.
SC 2015
Valéry Weber, Teodoro Laino, et al.
JCTC
Katharina Meier, Teodoro Laino, et al.
Journal of Physical Chemistry C