More Moore & more quality

Moore and more and symmetry

In any spatially discrete model of pedestrian motion which uses a regular lattice as basis, there is the question of how the symmetry between the different directions of motion can be restored as far as possible but with limited computational effort. This question is equivalent to the question " How important is the orientation of the axis of discretization for the result of the sim-ulation? " ...

Novel Si-Ge-C Superlattices for “More than Moore” CMOS

The search for Silicon-based direct band-gap semiconductors is more relevant than ever for “More than Moore” CMOS. Monolithically-integrated novel crystalline materials are key to enabling increased performance and new functionalities, such as efficient light absorption and emission. Si-Ge-C SuperLattices [1] are highly ordered synthetic crystals having direct band-gaps and large oscillator str...

SiGe BiCMOS Baseline Technology for More than Moore Functional Diversification

“More Than Moore” functional diversification by combining different technologies is enlarging the spectrum for embedded system applications. In this paper we focus on the monolithic integration approach of optical components into the front-endoff-line (FEOL) to combine electronics and photonics (Si Photonics), and of MEMS (microelectro-mechanical systems) into the back-end-offline (BEOL) of SiG...

Three-Dimensional Integration: A More Than Moore Technology

Three-dimensional integrated circuits (3D-ICs), which contain multiple layers of active devices, have the potential to dramatically enhance chip performance, functionality, and device packing density. They also provide for microchip architecture and may facilitate the integration of heterogeneous materials, devices, and signals and offer a promising solution for reducing both silicon footprint ...

Moore and more progress in electronics and photonics.