Abstract: A multi-gate total ionizing dose (TID) radiation-hardened device includes a semiconductor substrate on which a shallow trench isolation (STI) region and a plurality of Fin structures are provided. The STI region is provided between adjacent two Fin structures. A middle portion of a section of the STI region perpendicular to a source-drain direction is hollowed out. A surface of an upper part of each Fin structure not in contact with the STI structure is provided with a gate structure across the Fin structures. A part of the Fin structures in contact with the gate structure is configured as a channel region. A lower part of each Fin structure is covered by the STI region.

Abstract: A method for characterizing a fluctuation induced by single particle irradiation in a device. A plurality of devices varying in size are tested respectively before and after irradiation to obtain threshold voltage distribution, such that a threshold voltage fluctuation induced by irradiation is obtained and used to correct a process fluctuation model, so as to correct a design margin of the devices working under the irradiation.

Abstract: A method for characterizing a fluctuation induced by single particle irradiation in a device. A plurality of devices varying in size are tested respectively before and after irradiation to obtain threshold voltage distribution, such that a threshold voltage fluctuation induced by irradiation is obtained and used to correct a process fluctuation model, so as to correct a design margin of the devices working under the irradiation.

Abstract: The present invention discloses a radiation-hardened-by-design (RHBD) multi-gate device and a fabrication method thereof. The multi-gate device of the present invention includes a substrate; a source region and a drain region, which are on the substrate; a protruding fin structure and a field dielectric layer between the source region and the drain region on the substrate; a gate dielectric and a gate electrode on the fin structure and the dielectric layer; and two isolation layers separated to each other, which are disposed in the drain region between the adjacent two fins, wherein an interlayer is sandwiched between the two isolation layers.

Abstract: The present invention discloses a preparation method of a germanium-based Schottky junction, comprising, cleaning a surface of N-type germanium-based substrate, then depositing a layer of CeO2 on the surface, and further depositing a layer of metal. The stability Ce—O—Ge bonds can be formed at the interface after rare earth oxides CeO2 are in contact with the germanium substrate, and this is beneficial to reduce the interface state density, improve the quality of the interface, and reduce the MIGS and suppress Fermi-level pinning. Meanwhile, the tunneling resistance introduced by CeO2 between the metal and the germanium substrate is smaller relative to the case of Si3N4, Al2O3, Ge3N4 or the like. In view of the excellent surface characteristics and small conduction band offset relative to the germanium substrate, interposing of the CeO2 dielectric layer is applicable to the preparation the germanium-based Schottky junction having a low resistivity.

Abstract: The present invention discloses a preparation method of a germanium-based Schottky junction, comprising, cleaning a surface of N-type germanium-based substrate, then depositing a layer of CeO2 on the surface, and further depositing a layer of metal. The stability Ce—O—Ge bonds can be formed at the interface after rare earth oxides CeO2 are in contact with the germanium substrate, and this is beneficial to reduce the interface state density, improve the quality of the interface, and reduce the MIGS and suppress Fermi-level pinning. Meanwhile, the tunneling resistance introduced by CeO2 between the metal and the germanium substrate is smaller relative to the case of Si3N4, Al2O3, Ge3N4 or the like. In view of the excellent surface characteristics and small conduction band offset relative to the germanium substrate, interposing of the CeO2 dielectric layer is applicable to the preparation the germanium-based Schottky junction having a low resistivity.

Abstract: The present invention discloses a method for processing a gate dielectric layer deposited on a germanium-based or Group III-V compound-based substrate, belonging to a semiconductor device field. The method comprises the steps of depositing a high-K gate dielectric layer on the germanium-based or Group III-V compound-based substrate, and then performing a plasma process to the high-K gate dielectric layer by using fluorine plasma, wherein during the plasma process, a guiding electric field is applied so that fluorine ions, when being accelerated to a surface of the gate dielectric layer, has an energy of 5-50 eV and the fluorine plasma drifts into the high-K gate dielectric layer, a ratio of a density of the fluorine ions in the high-K gate dielectric layer and a density of oxygen atoms in the high-K gate dielectric layer being 0.01-0.15:1.

Abstract: The present invention discloses a radiation-hardened-by-design (RHBD) multi-gate device and a fabrication method thereof. The multi-gate device of the present invention includes a substrate; a source region and a drain region, which are on the substrate; a protruding fin structure and a field dielectric layer between the source region and the drain region on the substrate; a gate dielectric and a gate electrode on the fin structure and the dielectric layer; and two isolation layers separated to each other, which are disposed in the drain region between the adjacent two fins, wherein an interlayer is sandwiched between the two isolation layers.

Abstract: Disclosed herein is a method for isolating active regions in a germanium-based MOS device. A surface of a germanium-based substrate is covered by a thin polysilicon layer or a poly-SiGe layer, and an isolation structure of germanium dioxide covered by a silicon dioxide layer or a SiGe oxide layer on top is formed by means of two steps of oxidation in a case of the active regions are protected. Such two steps of oxidation using the polysilicon layer or the poly-SiGe layer as a sacrificial layer is advantageous to improve the isolation quality of a fabricated germanium dioxide and to reduce a beak effect occurred during a local field oxygen oxidation so as to dramatically elevate the performance of the germanium device.

Abstract: The present invention discloses a method for separating SOI device threshold voltage shift under a DC HCl stress, which belongs to a semiconductor reliability test field. By means of this method, under the condition that stressing bias is applied simultaneously to a gate terminal and a drain terminal of the SOI PMOSFET, the influences of HCl effect and NBTI effect are separated on the threshold voltage shift under the DC HCl stress. Adopting the present invention helps to better understand degradation mechanisms from HCl effect under stress with VG=VD, so as to better build model for the device and more accurately predict the device lifetime.

Abstract: A method for predicting a reliable lifetime of a SOI MOSFET device including: measuring a relationship of a gate resistance of the device varying as a function of a temperature at different wafer temperatures; performing a lifetime accelerating test on the device at different wafer temperatures, so as to obtain a degenerating relationship of a parameter representing the lifetime of the device as a function of stress time, and obtain a lifetime in the presence of self-heating when the parameter degenerates to 10%; performing a self-heating correction on the measured lifetime of the device by using the measured self-heating temperature and an Arrhenius model, so as to obtain a lifetime without self-heating influence; performing a self-heating correction on a variation of the drain current caused by self-heating; performing a self-heating correction on an impact ionization rate caused by hot carriers; and predicting the lifetime of the device under a bias.

Abstract: The present invention discloses a method for processing a gate dielectric layer deposited on a germanium-based or Group III-V compound-based substrate, belonging to a semiconductor device field. The method comprises the steps of depositing a high-K gate dielectric layer on the germanium-based or Group III-V compound-based substrate, and then performing a plasma process to the high-K gate dielectric layer by using fluorine plasma, wherein during the plasma process, a guiding electric field is applied so that fluorine ions, when being accelerated to a surface of the gate dielectric layer, has an energy of 5-50 eV and the fluorine plasma drifts into the high-K gate dielectric layer, a ratio of a density of the fluorine ions in the high-K gate dielectric layer and a density of oxygen atoms in the high-K gate dielectric layer being 0.01-0.15:1.

Abstract: Disclosed herein is a method for isolating active regions in a germanium-based MOS device. A surface of a germanium-based substrate is covered by a thin polysilicon layer or a poly-SiGe layer, and an isolation structure of germanium dioxide covered by a silicon dioxide layer or a SiGe oxide layer on top is formed by means of two steps of oxidation in a case of the active regions are protected. Such two steps of oxidation using the polysilicon layer or the poly-SiGe layer as a sacrificial layer is advantageous to improve the isolation quality of a fabricated germanium dioxide and to reduce a beak effect occurred during a local field oxygen oxidation so as to dramatically elevate the performance of the germanium device.

Abstract: A radiation resistant CMOS device and a method for fabricating the same. The CMOS device includes a substrate, a source region, a drain region and a vertical channel on the substrate. A first dielectric protection region is inserted into the vertical channel at the center of the vertical channel to divide the vertical channel into two parts and has a height equal to the length of the vertical channel. The edge of the first dielectric protection region is 20-100 nm from an outer side of the channel, with a central axis of an silicon platform for an active region as the center. A second dielectric protection region is disposed under the source or drain region, with a length equal to the length of the source or drain region and a height of 10-50 nm. The dielectric protection regions effectively block paths for the source and drain regions collecting charges.

Abstract: A CMOS device for reducing a radiation-induced charge collection and a method for fabricating the same. In the CMOS device, a heavily doped charge collection-suppressed region is disposed directly under the source region and the drain region. The region has a doping type opposite that of the source region and the drain region, and has a doping concentration not less than that of the source region and the drain region. The charge collection-suppressed region has a lateral part slightly less than or equal to that of the source region and the drain region, and has a lateral range toward to the channel not exceed the edges of the source region and the drain region. The CMOS device may greatly reduce a range of the funnel that appears under the action of a single particle, so that charges collected instantaneously under a force of an electric field may be reduced.

Abstract: The embodiments of the present invention provide a Ge-based NMOS device structure and a method for fabricating the same. By using the method, double dielectric layers of germanium oxide (GeO2) and metal oxide are deposited between the source/drain region and the substrate. The present invention not only reduces the electron Schottky barrier height of metal/Ge contact, but also improves the current switching ratio of the Ge-based Schottky and therefore, it will improve the performance of the Ge-based Schottky NMOS transistor. In addition, the fabrication process is very easy and completely compatible with the silicon CMOS process. As compared with conventional fabrication method, the Ge-based NMOS device structure and the fabrication method in the present invention can easily and effectively improve the performance of the Ge-based Schottky NMOS transistor.

Abstract: The present invention discloses a method for fabricating a semiconductor nano circular ring. In the method, firstly, a positive photoresist is coated on a semiconductor substrate, then the photoresist is exposed by using a circular mask with a micrometer-sized diameter to obtain the circular ring-shaped photoresist, based on the poisson diffraction principle. Then, a plasma etching is performed on the substrate under a protection of the circular ring-shaped photoresist to form a circular ring-shaped structure with a nano-sized wall thickness on a surface of the substrate. The embodiment of present invention fabricates a nano-sized circular ring-shaped structure by using a micrometer-sized lithography equipment and a micrometer-sized circular mask, and overcomes the dependence on advanced technologies, so as to effectively reduce the fabrication cost of the circular ring-shaped nano structure.

Abstract: The embodiments of the present invention provide a Ge-based NMOS device structure and a method for fabricating the same. By using the method, double dielectric layers of germanium oxide (GeO2) and metal oxide are deposited between the source/drain region and the substrate. The present invention not only reduces the electron Schottky barrier height of metal/Ge contact, but also improves the current switching ratio of the Ge-based Schottky and therefore, it will improve the performance of the Ge-based Schottky NMOS transistor. In addition, the fabrication process is very easy and completely compatible with the silicon CMOS process. As compared with conventional fabrication method, the Ge-based NMOS device structure and the fabrication method in the present invention can easily and effectively improve the performance of the Ge-based Schottky NMOS transistor.

Abstract: The present invention discloses a strained channel field effect transistor and a method for fabricating the same. The field effect transistor comprises a substrate, a source/drain, a gate dielectric layer, and a gate, characterized in that, an “L” shaped composite isolation layer, which envelops a part of a side face of the source/drain adjacent to a channel and the bottom of the source/drain, is arranged between the source/drain and the substrate; the composite isolation layer is divided into two layers, that is, an “L” shaped insulation thin layer contacting directly with the substrate and an “L” shaped high stress layer contacting directly with the source and the drain. The field effect transistor of such a structure improves the mobility of charge carriers by introducing stress into the channel by means of the high stress layer, while fundamentally improving the device structure of the field effect transistor and improving the short channel effect suppressing ability of the device.

Abstract: The present invention discloses a CMOS device of reducing charge sharing effect and a fabrication method thereof. The present invention has an additional isolation for trapping carriers disposed right below an isolation region. the material of the additional isolation region is porous silicon. Since porous silicon is a functional material of spongy structure by electrochemistry anodic oxidizing monocrystalline silicon wafer, there are a large number of microvoids and dangling bonds on the surface layer of the porous silicon. These defects may form defect states in a center of forbidden band of the porous silicon, the defect states may trap carriers so as to cause an increased resistance. And with an increase of density of corrosion current, porosity increases, and defects in the porous silicon increase.