Abstract: The invention provides a method of controlling the spatial distribution, shape and size of films of conjugated organic molecules that can be used to grow single layers of organic molecules on silicon oxide nanostructures. The silicon oxide nanostructures are produced using an anodic oxidation process. The organisation of the molecules on the oxide nanostructures is dependent on the kinetic parameters of the latter (evaporation rate, diffusion coefficient) and on the interactions with the silicon (anodic) oxide regions. The molecules form domains which exactly reproduce the lateral size and the shape of the oxide nanostructures. The invention provides a powerful method of performing a bottom-up construction of wires, electrodes and charge transfer zones in nanoscale devices.

Abstract: A novel method for growing semiconductor material including GaN is disclosed. The method involves placing a first substance into a growth reactor, supplying a second gaseous substance into the grouth reactor, and applying electrical field to the second gaseous substance to produce the cry stalline compound material.

Abstract: A method for producing a silicon ingot having a directional solidification structure comprising the steps of: placing a silicon raw material into a crucible of a melting device constructed by mounting a chill plate on an underfloor heater, mounting a crucible with a large cross-sectional area on the chill plate, providing an overhead heater over the crucible, and surrounding the circumference of the crucible with a heat insulator; heat-melting the silicon raw material by flowing an electric current through the underfloor heater and overhead heater; chilling the bottom of the crucible by halting the electric current through the underfloor heater after the silicon raw material has been completely melted to form a molten silicon; chilling the bottom of the crucible by flowing an inert gas through the chill plate; and intermittently or continuously lowering the temperature of the overhead heater by intermittently or continuously decreasing the electric current through the overhead heater, and an apparatus for pro

Abstract: A method for surface flattening a crystal substrate includes (a) processing a surface of a silicon single crystal substrate, the surface deviating by 0.1.degree. or less from the (001) plane, so as to form a processed zone thereon which is an obstacle to the movement of surface steps present on the surface of the silicon single crystal substrate and which is adjacent to a preselected region having a surface to be flattened when viewed on an atomic level; (b) holding the substrate processed in step (a) in a chamber having an adjustable degree of vacuum so that the substrate has a temperature which is controlled by direct-current passage and heating; and (c) heating the substrate to move the surface steps along the substrate from the preselected region and gather the surface steps in the processed zone, thereby forming a flat surface in the preselected region of the substrate when viewed on the atomic level.