Abstract: A process simulation method includes: converting condition data of plasma doping for introducing an impurity into a semiconductor in a plasma atmosphere to corresponding condition data of ion implantation for implanting impurities as an ion beam into the semiconductor; and calculating device structure data on the basis of the ion implantation condition data converted from the plasma doping condition data.

Abstract: A semiconductor memory device according to an embodiment of the present invention includes a substrate, a first gate insulator formed on the substrate and serving as an F-N (Fowler-Nordheim) tunneling film, a first floating gate formed on the first gate insulator, a second gate insulator formed on the first floating gate and serving as an F-N tunneling film, a second floating gate formed on the second gate insulator, an intergate insulator formed on the second floating gate and serving as a charge blocking film, and a control gate formed on the intergate insulator, at least one of the first and second floating gates including a metal layer.

Abstract: According to an aspect of the present invention, there is provided a nonvolatile semiconductor memory device including: a semiconductor substrate; memory cell transistors that are series-connected; and a select transistor that includes: a first diffusion region that is formed in the semiconductor substrate at one end of the memory cell transistors; a first insulating film that is formed on the semiconductor substrate at a side of the first diffusion region; a select gate electrode that is formed on the first insulating film; a semiconductor pillar that is formed to extend upward from the semiconductor substrate and to be separated from the select gate electrode; a second insulating film that is formed between the select gate electrode and the semiconductor pillar; and a second diffusion region that is formed on the semiconductor pillar.

Abstract: A semiconductor storage device has a semiconductor substrate, a plurality of first insulating films formed on the semiconductor substrate with predetermined spacing therebetween, an element isolation region formed between the first insulating films in a first direction, a floating gate electrode comprising a first charge accumulation film formed on the first insulating film, a second charge accumulation film formed on the first charge accumulation film and having a width in a second direction orthogonal to the first direction smaller than the width of the first charge accumulation film, and a third charge accumulation film formed on the second charge accumulation film and having the width in the second direction larger than the width of the second charge accumulation film, a second insulating film formed on the second charge accumulation film and between the second charge accumulation film and the element isolation region, a third insulating film formed on the charge accumulation film and the element isolatio

Abstract: A process simulation method includes: converting condition data of plasma doping for introducing an impurity into a semiconductor in a plasma atmosphere to corresponding condition data of ion implantation for implanting impurities as an ion beam into the semiconductor; and calculating device structure data on the basis of the ion implantation condition data converted from the plasma doping condition data.

Abstract: A method of manufacturing a semiconductor device includes forming a mask layer on a first-conductivity-type semiconductor substrate, etching the semiconductor substrate using the mask layer as a mask, thereby forming a projecting semiconductor layer, forming a first insulating layer on the semiconductor substrate to cover a lower portion of the projecting semiconductor layer, doping a first-conductivity-type impurity into the first insulating layer, thereby forming a high-impurity-concentration layer in the lower portion of the projecting semiconductor layer, forming gate insulating films on side surfaces of the projecting semiconductor layer which upwardly extend from an upper surface of the first insulating layer, and forming a gate electrode on the gate insulating films and on the first insulating film.

Abstract: A method of manufacturing a semiconductor device includes forming a mask layer on a first-conductivity-type semiconductor substrate, etching the semiconductor substrate using the mask layer as a mask, thereby forming a projecting semiconductor layer, forming a first insulating layer on the semiconductor substrate to cover a lower portion of the projecting semiconductor layer, doping a first-conductivity-type impurity into the first insulating layer, thereby forming a high-impurity-concentration layer in the lower portion of the projecting semiconductor layer, forming gate insulating films on side surfaces of the projecting semiconductor layer which upwardly extend from an upper surface of the first insulating layer, and forming a gate electrode on the gate insulating films and on the first insulating film.

Abstract: A semiconductor device of an example of the invention comprises a memory cell and a select gate transistor provided for the memory cell. A gate electrode of the select gate transistor has a Tri-gate structure in which an upper surface of a gate insulating film formed above a channel of the select gate transistor is set higher than a portion of an upper surface of an element isolation region of the select gate transistor.

Abstract: According to an aspect of the present invention, there is provided a nonvolatile semiconductor memory device including: a semiconductor substrate; memory cell transistors that are series-connected; and a select transistor that includes: a first diffusion region that is formed in the semiconductor substrate at one end of the memory cell transistors; a first insulating film that is formed on the semiconductor substrate at a side of the first diffusion region; a select gate electrode that is formed on the first insulating film; a semiconductor pillar that is formed to extend upward from the semiconductor substrate and to be separated from the select gate electrode; a second insulating film that is formed between the select gate electrode and the semiconductor pillar; and a second diffusion region that is formed on the semiconductor pillar.

Abstract: A semiconductor device with a fin structure according to one embodiment of the present invention includes: a fin of a predetermined height formed on an insulating layer of a substrate; a gate electrode formed on both sides of the fin through a gate insulating film; and a source/drain region formed in the fin on both sides of the gate electrode by implanting impurities into the fin; wherein a concentration of the impurities forming the source/drain region in a vicinity of an interface between the fin and the insulating layer in the fin is lower than a concentration of the impurities in a vicinity of the interface between the fin and the insulating layer in the insulating layer.

Abstract: A Monte Carlo ion implantation simulation method includes finding a unit cell in which an implanted trial particle is present, finding a basic cell in which the trial particle is present among basic cells that form the unit cell, finding a directional range in which the trial particle travels, obtaining collision candidate atoms with their locations from a database according to the found basic cell and directional range, setting a thermal vibration displacement for each of the collision candidate atoms that has not set thermal vibration displacement, calculating a collision parameter and free-flight distance for each of the collision candidate atoms, selecting, as a collision atom, one of the collision candidate atoms that has a collision parameter smaller than a predetermined maximum collision parameter and a smallest positive free-flight distance, and calculating a collision between the trial particle and the collision atom to find the after-collision location and momentum of the trial particle.

Abstract: A method of manufacturing a semiconductor device includes forming a mask layer on a first-conductivity-type semiconductor substrate, etching the semiconductor substrate using the mask layer as a mask, thereby forming a projecting semiconductor layer, forming a first insulating layer on the semiconductor substrate to cover a lower portion of the projecting semiconductor layer, doping a first-conductivity-type impurity into the first insulating layer, thereby forming a high-impurity-concentration layer in the lower portion of the projecting semiconductor layer, forming gate insulating films on side surfaces of the projecting semiconductor layer which upwardly extend from an upper surface of the first insulating layer, and forming a gate electrode on the gate insulating films and on the first insulating film.

Abstract: A system for preparing manufacturing-process specifications employs process data serving both for a production control system and a simulation system, and effectively uses a result of simulation. The system prepares the manufacturing-process specifications through the steps of controlling apparatuses according to the manufacturing-process specifications, to carry out manufacturing processes; collecting data measured through the manufacturing processes; simulating the manufacturing processes according to corresponding models and parameters; correcting the models and parameters according to the collected data; and amending the manufacturing-process specifications according to a result of the simulation.

Abstract: A Monte Carlo ion implantation simulation method speedily calculates an implanted ion distribution in a semiconductor substrate.

Abstract: Process simulation for LSIs and other semiconductor devices will handle plural same impurities introduced in different processes as different impurities. Thus, by handling them as different impurities in calculation, it is possible to obtain the distribution profiles of impurities in semiconductor devices without being effected by another same impurity introduced in another process or a number of processes during processing. With this, even a plurality of process conditions are discussed or when one or some of process(es) in a sequence of semiconductor device fabrication processes is (are) changed in procedure, it is not necessary to repeat the process simulation many times from the beginning. And it is possible to easily decide which process must be changed in conditions based on a finally obtained structure of semiconductor devices.