Patent application number | Description | Published |
20120018775 | ELECTROSTATIC DISCHARGE PROTECTION DEVICE AND METHOD FOR FABRICATING THE SAME - The present invention provides an ESD protection device comprising a SCR structure that is a transverse PNPN structure formed by performing a P-type implantation and an N-type implantation in an N-well and a P-well on a silicon substrate, respectively, wherein a P-type doped region in the N-well is used as an anode, and N-type doped region in the P-well is used as a cathode, characterized in that, N-type dopants are implanted into the N-well to form one lead-out terminal of a resistor, P-type dopants are implanted into the P-well to form another lead-out terminal for the resistor, and the two leading-out terminals are connected by the resistor. | 01-26-2012 |
20120032239 | METHOD FOR INTRODUCING CHANNEL STRESS AND FIELD EFFECT TRANSISTOR FABRICATED BY THE SAME - The present invention relates to CMOS ultra large scale integrated circuits, and provides a method for introducing channel stress and a field effect transistor fabricated by the same. According to the present invention, a strained dielectric layer is interposed between source/drain regions and a substrate of a field effect transistor, and a strain is induced in a channel by the strained dielectric layer which directly contacts the substrate, so as to improve a carrier mobility of the channel and a performance of the device. The specific effects of the invention include: a tensile strain may be induced in the channel by using the strained dielectric layer having a tensile strain in order to increase an electron mobility of the channel; a compressive strain may be induced in the channel by using the strained dielectric layer having a compressive strain in order to increase a hole mobility of the channel. According to the invention, not only an effectiveness of the introduction of channel stress is ensued, but the device structure of the field effect transistor is also improved fundamentally, so that a capability for suppressing a short channel effect of the device is increased. | 02-09-2012 |
20120061637 | 3-D STRUCTURED NONVOLATILE MEMORY ARRAY AND METHOD FOR FABRICATING THE SAME - The present invention relates to a field of nonvolatile memory technology in ULSI circuits manufacturing technology and discloses a 3D-structured resistive-switching memory array and a method for fabricating the same. The 3D-structured resistive-switching memory array according to the invention includes a substrate and a stack structure of bottom electrodes/isolation dielectric layers, deep trenches are etched in the stack structure of the bottom electrodes/the isolation dielectric layers; a resistive-switching material layer and a top electrode layer are deposited on sidewalls of the deep trenches, wherein the top electrodes and the bottom electrodes are crossed over each other on the sidewalls of the deep trenches with the resistive-switching material being interposed at cross-over points, each of the cross-over points forms one resistive-switching memory cell, and all of the resistive-switching memory cells form the 3D-structured resistive-switching memory array, and the 3D resistive-switching memory in the array are isolated by the isolation dielectric layers. According to the invention, the storage density of a resistive-switching memory can be improved, the process can be simplified, and the cost of the process can be reduced. | 03-15-2012 |
20120099381 | EMBEDDED NON-VOLATILE MEMORY CELL, OPERATION METHOD AND MEMORY ARRAY THEREOF - The present invention discloses an embedded non-volatile memory cell, an operation method and a memory array thereof. The method includes using a gate of a selection transistor as a floating gate of a memory, and using a source electrode and a drain electrode of the selection transistor as a source electrode and a drain electrode of the memory; and then changing a threshold of the device by varying the electrode voltages, thereby realizing a storage and change of information. The invention has advantages of a small area, a low operating voltage, high operating speed and high reliability. | 04-26-2012 |
20120113726 | FLASH MEMORY AND FABRICATION METHOD AND OPERATION METHOD FOR THE SAME - The present invention discloses a flash memory and the fabrication method and the operation method for the same. The flash memory comprises two memory cells of vertical channels, wherein a lightly-doped N type (or P type) silicon is used as a substrate; a P+ region (or an N+ region) is provided on each of the both ends of the silicon surface, and two channel regions perpendicular to the surface are provided therebetween; an N+ region (or a P+ region) shared by two channels is provided over the channels; a tunneling oxide layer, a polysilicon floating gate, a block oxide layer and a polysilicon control gate are provided sequentially on the outer sides of each channel from inside to outside; and the polysilicon floating gate and the polysilicon control gate are isolated from the P+ region by a sidewall oxide layer. The whole device is a two-bit TFET type flash memory with vertical channels which has better compatibility with prior-art standard CMOS process. As compared with a conventional MOSFET-based flash memory, the flash memory according to the present invention possesses various advantages such as high programming efficiency, low power consumption, effective inhibition of punch-through effect, and high density, etc. | 05-10-2012 |
20120115297 | METHOD FOR FABRICATING A TUNNELING FIELD-EFFECT TRANSISTOR - The present invention discloses a method for self-alignedly fabricating tunneling field-effect transistor (TFET) based on planar process, thereby lowering requirements on a photolithography process for fabricating the planar TFET. In the method, the source region and the drain region of the TFET are not directly defined by photolithography; rather, they are defined by another dielectric film which locates over an active region and on both sides of the gate and which is different from the dielectric film that defines the channel region. The influence due to the alignment deviation among three times of photolithography process for defining the channel region, the source and the drain regions may be eliminated by selectively removing the dielectric film over the source and drain regions by wet etching. Therefore, a planar TFET may be fabricated self-alignedly based on this process, thereby the rigid requirements on the alignment deviation of the photolithography during the fabrication procedure of a planar TFET is alleviated, which facilitates to fabricate a planar TFET device with stable and reliable characteristics. | 05-10-2012 |
20120168770 | HEAT DISSIPATION STRUCTURE OF CHIP - A heat dissipation structure of a chip in the field of microelectronics is provided. The heat dissipation structure includes a P-type superlattice layer and an N-type superlattice layer formed over an upper surface of the chip by oxidation isolation. The P-type superlattice and the N-type superlattice are isolated by silicon oxide. Through a contact hole the P-type superlattice is electrically connected to a metal layer that is applied with a low potential in the chip, and a metal layer to be connected with an external power source is formed over the P-type superlattice. Through a contact hole the N-type superlattice is electrically connected to a metal layer that is applied with a high-potential power source in the chip, and a metal layer to be connected with an external power source is formed over the N-type superlattice. The potential of the external power source connected with the P-type superlattice is lower than that of the external power source connected with the N-type superlattice. The present invention can achieve heat dissipation of the chip and meanwhile prevent the ambient heat from transferring into the chip, by using the feature that the superlattice has a low thermal conductivity and phonon-localization-like behavior. | 07-05-2012 |
20120181584 | Resistive Field Effect Transistor Having an Ultra-Steep Subthreshold Slope and Method for Fabricating the Same - The invention discloses a resistive field effect transistor (ReFET) having an ultra-steep subthreshold slope, which relates to a field of field-effect-transistor logic device and circuit in CMOS ultra-large-scale-integrated circuit (ULSI). The resistive field effect transistor comprises a control gate electrode layer, a gate dielectric layer, a semiconductor substrate, a doped source region and a doped drain region, wherein the control gate is configured to adopt a stacked gate structure in which a bottom layer or a bottom electrode layer, a middle layer or a resistive material layer, and a top layer or a top electrode layer are sequentially formed. Compared with the existing methods for breaking the conventional subthreshold slope limititation, the device of the invention has a larger on-current, a lower operation voltage, and a better subthreshold feature. | 07-19-2012 |
20120181585 | Combined-source Mos Transistor with Comb-shaped Gate, and Method for Manufacturing the Same - The present invention discloses a combined-source MOS transistor with a Schottky Barrier and a comb-shaped gate structure, and a method for manufacturing the same. The combined-source MOS transistor includes: a control gate electrode layer, a gate dielectric layer, a semiconductor substrate, a highly-doped source region and a highly-doped drain region, wherein a Schottky source region is connected to a side of the highly-doped source region which is far from a channel, one end of the control gate extends to the highly-doped source region, the extended gate region is an extension gate in a form of a comb-shaped and the original control gate region is a main gate; an active region covered by the extension gate is also a channel region, and is a substrate material; the highly-doped source region which is formed by highly doping is located on both sides of each comb finger of the extension gate; and a Schottky junction is formed at a location where the Schottky source region and the channel under the extension gate are located. As compared with an existing MOSFET, in the invention, a higher turn-on current, a lower leakage current and a steeper subthreshold slope may be obtained under the same process condition and the same active region size. | 07-19-2012 |
20120187495 | SEMICONDUCTOR DEVICE AND METHOD FOR FABRICATING THE SAME - The present invention provides a semiconductor device and a method for fabricating the same, wherein the method comprises: providing a germanium-based semiconductor substrate having a plurality of active regions and device isolation regions between the plurality of the active regions, wherein a gate dielectric layer and a gate over the gate dielectric layer are provided on the active regions, and the active regions include source and drain extension regions and deep source and drain regions; performing a first ion implantation process with respect to the source and drain extension regions, wherein the ions implanted in the first ion implantation process include silicon or carbon; performing a second ion implantation process with respect to the source and drain extension regions; performing a third ion implantation process with respect to the deep source and drain regions; performing an annealing process with respect to the germanium-based semiconductor substrate which has been subjected to the third ion implantation process. According to the method for fabricating a semiconductor device, through the implantation of silicon impurities, appropriate stress may be introduced into the germanium channel effectively by the mismatch of lattices in the source and drain regions, so that the mobility of electrons in the channel is enhanced and the performance of the device is improved. | 07-26-2012 |
20120187976 | METHOD FOR TESTING TRAP DENSITY OF GATE DIELECTRIC LAYER IN SEMICONDUCTOR DEVICE HAVING NO SUBSTRATE CONTACT - A method for testing trap density in a gate dielectric layer of a semiconductor device having no substrate contact is provided in the invention. A source and a drain of the device are bilateral symmetric, and probes and cables of a test instrument connecting to the source and the drain are bilateral symmetric. Firstly, bias settings at the gate, the source and the drain are controlled so that the device is under an initial state that an inversion layer is not formed and traps in the gate dielectric layer impose no confining effects on charges. After that, the following steps are repeated sequentially to form a loop by changing the bias settings: 1) carriers flow into the channel through the source and the drain to form an inversion layer, and a portion of carriers are confined by the traps in the gate dielectric layer; 2) carriers of the inversion layer flow back to the source and the drain respectively, whereas the carriers confined by the traps in the gate dielectric layer do not flow back to the channel; 3) carriers confined by the traps in the gate dielectric layer flow out through the drain terminal only; and the trap density of the gate dielectric layer are calculated according to the period of the loop, the size of the channel of the device, and DC currents at the source and the drain. The method is simple and effective and is easy to setup the instruments with a low cost. The method is applicable to be used in testing traps in the gate dielectric layer of the devices that have no substrate contact, especially the surrounding-gate device. | 07-26-2012 |
20120188821 | METHOD FOR ACHIEVING FOUR-BIT STORAGE USING FLASH MEMORY HAVING SPLITTING TRENCH GATE - The present invention discloses a method for achieving four-bit storage by using a flash memory having a splitting trench gate. The flash memory with the splitting trench gate is disclosed in a Chinese patent No. 200710105964.2. At one side that each of two trenches is contacted with a channel, a programming for electrons is achieved by using a channel hot electron injection method; and at the other side that each of the two trenches is contacted with a source or a drain, a programming for electrons is achieved by using an FN injection method, so that a function of a four-bit storage of the device is achieved by changing a programming mode. Thus, a performance of the device is improved while a storage density is greatly increased. | 07-26-2012 |
20120190202 | METHOD FOR FABRICATING SEMICONDUCTOR NANO CIRCULAR RING - 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. | 07-26-2012 |
20120199808 | HIGH VOLTAGE-RESISTANT LATERAL DOUBLE-DIFFUSED TRANSISTOR BASED ON NANOWIRE DEVICE - The present invention provides a high voltage-resistant lateral double-diffused transistor based on a nanowire device, which relates to the field of microelectronics semiconductor devices. The lateral double-diffused MOS transistor includes a channel region, a gate dielectric, a gate region, a source region, a drain region, a source end extension region and a drain end S-shaped drifting region, wherein the channel region has a lateral cylindrical silicon nanowire structure, on which a layer of gate dielectric is uniformly covered, the gate region is on the gate dielectric, the gate region and the gate dielectric completely surround the channel region, the source end extension region lies between the source region and the channel region, the drain end S-shaped drifting region lies between the drain region and the channel region, the plan view of the drain end S-shaped drifting region is in the form of single or multiple S-shaped structure(s), and an insulating material with a relative dielectric constant of 1-4 is filled within the S-shaped structure(s). The invention can improve the high voltage-resistant capability of a lateral double-diffused transistor based on a silicon nanowire MOS transistor. | 08-09-2012 |
20120223361 | LOW-POWER CONSUMPTION TUNNELING FIELD-EFFECT TRANSISTOR WITH FINGER-SHAPED GATE STRUCTURE - The present invention discloses a low-power consumption tunnelling field-effect transistor (TFET). The TFET according to the invention includes a source, a drain and a control gate, wherein the control gate extends towards the source to form a finger-type control gate, which includes an extended gate region and an original control gate region, and an active region covered by the extended gate region is also an channel region and is made of the substrate material. The invention employs a finger-shaped gate structure, and the source region of the TFET surrounds the channel so that the on-state current of the device is improved. In comparison with the conventional planar TFET, a higher on-state current and a steeper subthreshold slope may be obtained under the same process conditions and with the same active region size. | 09-06-2012 |
20120238097 | METHOD FOR FABRICATING FINE LINE - Disclosed herein is a method for fabricating a fine line, which belongs to a field of ultra-large-scale integrated circuit manufacturing technology. In the invention, three trimming mask processes are performed to effectively improve a profile of the line and greatly reduce the LER (line edge roughness) of the line. At the same time, the invention is combined with a sidewall process, so that a nano-scaled fine line can be successfully fabricated and precisely controlled to 20 nm. Thus, a nano-scaled line with an optimized LER can be fabricated over the substrate. | 09-20-2012 |
20120241712 | Resistive-Switching Memory and Fabrication Method Thereof - The present invention discloses a resistive-switching memory and the fabrication method thereof. The resistive-switching memory comprises a substrate, a top electrode, a bottom electrode, and a resistive-switching material interposed between the top and bottom electrodes, wherein the central portion of the bottom electrode protrudes upwards to form a peak shape, and the top electrode is in a plate shape. The peak structure of the bottom electrode reduces power consumption of the device. The fabrication method thereof comprises forming peak structures on the surface of the substrate by means of corrosion, and then growing bottom electrodes thereon to form bottom electrodes having peak shapes, and depositing resistive-switching material and top electrodes. The entire fabrication process is simple, and high integration degree of the device can be achieved. | 09-27-2012 |
20120243313 | SEMICONDUCTOR MEMORY ARRAY AND METHOD FOR PROGRAMMING THE SAME - The invention provides a flash memory array structure and a method for programming the same, which relates to a technical field of nonvolatile memories in ultra large scale integrated circuit fabrication technology. The flash memory array of the present invention includes memory cells, word lines and bit lines connected to the memory cells, wherein the word lines connected to control gates of the memory cells and the bit lines connected to drain terminals of the memory cells are not perpendicular to each other but cross each other at an angle; the control gates of two memory cells adjacent to each other along the channel direction between every two bit lines are controlled by two word lines, respectively, drain terminals thereof are controlled by two bit lines, respectively, and source terminals thereof are shared. The present invention also provides a method for programming the flash memory array structure, which can realize a programming with low power consumption. | 09-27-2012 |
20120261740 | FLASH MEMORY AND METHOD FOR FABRICATING THE SAME - The present invention discloses a flash memory and a method for fabricating the same, and relates to the technical field of the semiconductor memory. The flash memory includes a buried oxygen layer on which a source terminal, a channel, and a drain terminal are disposed, wherein the channel is between the source terminal and the drain terminal, and a tunneling oxide layer, a polysilicon floating gate, a blocking oxide layer, and a polysilicon control gate are sequentially disposed on the channel, and a thin silicon nitride layer is disposed between the source terminal and the channel. The method includes: 1) performing a shallow trench isolation on a SOI silicon substrate to form an active region; 2) sequentially forming a tunneling oxide layer and a first polysilicon layer on the SOI silicon substrate to form a polysilicon floating gate, and forming a blocking oxide layer and a second polysilicon layer to form a polysilicon control gate; 3) etching the resultant structure to form a gate stack structure; 4) forming a drain terminal at one side of the gate stack structure, etching the silicon film at the other side of the gate stack structure, growing a thin silicon nitride layer, and then refilling the hole structure with silicon material, to form a source terminal. The method has the advantages of high programming efficiency, low power consumption, effectively preventing source-drain punchthrough effect. | 10-18-2012 |
20120264311 | SURFACE TREATMENT METHOD FOR GERMANIUM BASED DEVICE - The present invention provides a surface treatment method for germanium based device. Through performing surface pretreatment to the germanium based device by using an aqueous solution of ammonium fluoride as a passivant, the interface state may be reduced, the formation of natural oxidation layer at the germanium surface may be inhibited, the regeneration of natural oxidation layer and the out-diffusion of the germanium based substrate material can be effectively inhibited, and the thermal stability of the metal germanide may also be increased significantly, so that the interface quality of the germanium based device is improved easily and effectively, which are advantageous to improve the performance of the germanium based transistor. | 10-18-2012 |
20120267700 | TUNNELING CURRENT AMPLIFICATION TRANSISTOR - The present invention discloses a tunneling current amplification transistor, which relates to an area of field effect transistor logic devices in CMOS ultra large scale semiconductor integrated circuits (ULSI). The tunneling current amplification transistor includes a semiconductor substrate, a gate dielectric layer, an emitter, a drain, a floating tunneling base and a control gate, wherein the drain, the floating tunneling base and the control gate forms a conventional TFET structure, and a doping type of the emitter is opposite to that of the floating tunneling base. A position of the emitter is at the other side of the floating tunneling base with respect to the drain. A type of the semiconductor between the emitter and the floating tunneling base is the same as that of the floating tunneling base. As compared with the conventional TFET, the tunneling current amplification transistor of the present invention can increase the on-current of the device effectively and increase the driving capability of the device. | 10-25-2012 |
20120289004 | FABRICATION METHOD OF GERMANIUM-BASED N-TYPE SCHOTTKY FIELD EFFECT TRANSISTOR - The present invention discloses a fabrication method of a Ge-based N-type Schottky field effect transistor and relates to a filed of ultra-large-scaled integrated circuit fabrication process. The present invention forms a thin high K dielectric layer between a substrate and a metal source/drain. The thin layer on one hand may block the electron wave function of metal from inducing an MIGS interface state in the semiconductor forbidden band, on the other hand may passivate the dangling bonds at the interface of Ge. Meanwhile, since the insulating dielectric layer has a very thin thickness, and electrons can substantially pass freely, the parasitic resistances of the source and the drain are not significantly increased. The method can weaken the Fermi level pinning effect, cause the Fermi energy level close to the position of the conduction band of Ge and lower the electron barrier, thereby increasing the current switching ratio of the Ge-based Schottky transistor and improve the performance of the NMOS device. | 11-15-2012 |
20120302014 | METHOD FOR FABRICATING SURROUNDING-GATE SILICON NANOWIRE TRANSISTOR WITH AIR SIDEWALLS - A method for fabricating a surrounding-gate silicon nanowire transistor with air sidewalls is provided. The method is compatible with the CMOS process; the introduced air sidewalls can reduce the parasitic capacitance effectively and increase the transient response characteristic of the device, thus being applicable to a high-performance logic circuit. | 11-29-2012 |
20120302027 | Method for Fabricating Silicon Nanowire Field Effect Transistor Based on Wet Etching - Disclosed herein is a method for fabricating a silicon nanowire field effect transistor based on a wet etching. The method includes defining an active region; depositing a silicon oxide film as a hard mask, forming a pattern of a source and a drain and a fine bar connecting the source and the drain; transferring the pattern on the hard mask to a silicon substrate by performing etching process for the silicon substrate; performing ion implanting; etching the silicon substrate by wet etching, so that the silicon fine bar connecting the source and the drain is suspended; reducing the silicon fine bar to a nano size to form a silicon nanowire; depositing a polysilicon film; forming a polysilicon gate line acrossing the silicon nanowire by electron beam lithography and forming a structure of nanowire-all-around; forming a silicon oxide sidewall at both sides of the polysilicon gate line, by depositing a silicon oxide film and subsequently etching the silicon oxide film; forming the source and the drain by using ion implantation and high temperature annealing, so that the silicon nanowire field effect transistor is finally fabricated. The method is compatible with a conventional integrated circuit fabrication technology. The fabrication process is simple and convenient, and has a short cycle. | 11-29-2012 |
20120313154 | MOS Transistor Having Combined-Source Structure With Low Power Consumption and Method for Fabricating the Same - The present invention discloses a MOS transistor having a combined-source structure with low power consumption, which relates to a field of field effect transistor logic devices and circuits in CMOS ultra-large-scaled integrated circuits. The MOS transistor includes a control gate electrode layer, a gate dielectric layer, a semiconductor substrate, a Schottky source region, a highly-doped source region and a highly-doped drain region. An end of the control gate extends to the highly-doped source region to form a T shape, wherein the extending region of the control gate is an extending gate and the remaining region of the control gate is a main gate. The active region covered by the extending gate is a channel region, and material thereof is the substrate material. A Schottky junction is formed between the Schottky source region and the channel under the extending gate. The combined-source structure according to the invention combines a Schottky barrier and a T-shaped gate, improves the performance of the device, and the fabrication method thereof is simple. Thus, a higher turn-on current, a lower leakage current, and a steeper subthreshold slope can be obtained, and the present application can be applied in the field of low power consumption and have a higher practical value. | 12-13-2012 |
20130001655 | Heat Dissipation Structure of SOI Field Effect Transistor - The present invention discloses a heat dissipation structure for a SOI field effect transistor having a schottky source/drain, which relates to a field of microelectronics. The heat dissipation structure includes two holes connected with a drain terminal or with both a source terminal and a drain terminal, which are filled with an N-type material with high thermoelectric coefficient and a P-type material with high thermoelectric coefficient respectively. A metal wire for the N-type material with high thermoelectric coefficient in the vicinity of the drain terminal is applied a high potential with respect to the drain terminal, and a metal wire for the P-type material with high thermoelectric coefficient in the vicinity of the drain terminal is applied a low potential with respect to the drain terminal. A metal wire for the N-type material with high thermoelectric coefficient in the vicinity of the source terminal is applied a high potential with respect to the source terminal, and a metal wire for the P-type material in the vicinity of the source terminal is applied a lower potential with respect to the source terminal. By way of a Peltier effect, in the present invention heat can be absorbed at a contact portion between the thermoelectric material and the source/drain, and at the same time dissipated at a connection portion between the thermoelectric material and a bottom electrode metal, so that the heat generated in an active region of the device is effectively transferred to the substrate and dissipated through a heat sink. | 01-03-2013 |
20130011980 | FABRICATION METHOD OF VERTICAL SILICON NANOWIRE FIELD EFFECT TRANSISTOR - The present invention discloses a fabrication method of a vertical silicon nanowire field effect transistor having a low parasitic resistance, which relates to a field of an ultra-large-integrated-circuit fabrication technology. As compared with a conventional planar field effect transistor, on one hand the vertical silicon nanowire field effect transistor fabricated by the present invention can provide a good ability for suppressing a short channel effect due to the excellent gate control ability caused by the one-dimensional structure, and reduce a leakage current and a drain-induced barrier lowering (DIBL). On the other hand, an area of the transistor is further reduced and an integration degree of an IC system is increased. | 01-10-2013 |
20130013245 | METHOD FOR OBTAINING DISTRIBUTION OF CHARGES ALONG CHANNEL IN MOS TRANSISTOR - The present invention discloses a method for obtaining a distribution of charges along a channel of a MOS transistor, which is used for obtaining distributions of interface states charges and charges of a gate dielectric layer in the MOS transistor. The method includes: adding a MOS transistor into a test circuit; measuring two charge pumping current curves when a source terminal is open-circuited or when a drain terminal is open-circuited before and after a stress is applied by using a charge pumping current test method, where one of the two charge pumping current curves is an original curve and the other one is an post-stress curve; finding a point B corresponding to a point A on the original curve on the post-stress curve, and estimating amount of locally-generated interface states charges and charges of the gate dielectric layer by a variation of the charge pumping current and a variation in a voltage at a local point. As compared with a conventional method for obtaining a distribution, the method of the present invention can obtain a distribution of charges along a direction form the drain or source terminal to the channel more easily and rapidly, with an aid of a computer. A mass of complicated and repeated tests are reduced. Also, the method can provide an effective base for improving device reliability. | 01-10-2013 |
20130017654 | FABRICATION METHOD FOR SURROUNDING GATE SILICON NANOWIRE TRANSISTOR WITH AIR AS SPACERSAANM Huang; RuAACI BeijingAACO CNAAGP Huang; Ru Beijing CNAANM Zhuge; JingAACI BeijingAACO CNAAGP Zhuge; Jing Beijing CNAANM Fan; JiewenAACI BeijingAACO CNAAGP Fan; Jiewen Beijing CNAANM Ai; YujieAACI BeijingAACO CNAAGP Ai; Yujie Beijing CNAANM Wang; RunshengAACI BeijingAACO CNAAGP Wang; Runsheng Beijing CNAANM Huang; XinAACI BeijingAACO CNAAGP Huang; Xin Beijing CN - The invention discloses a fabrication method for a surrounding gate silicon nanowire transistor with air as spacers. The method comprises: performing isolation, and depositing a material A which has a higher etch selectivity ratio with respect to Si; performing photolithography to define a Fin hard mask; etching the material A to form the Fin hard mask; performing source and drain implantation; performing photolithography to define a channel region and large source/drain regions; forming the Si Fin and the large source/drains; removing the hard mask of the material A; forming a nanowire; etching the SiO | 01-17-2013 |
20130043515 | Strained Channel Field Effect Transistor and the Method for Fabricating the Same - 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. | 02-21-2013 |
20130069031 | MULTILEVEL RESISTIVE MEMORY HAVING LARGE STORAGE CAPACITY - The present invention discloses a multilevel resistive memory having large storage capacity, which belongs to a field of a fabrication technology of a resistive memory. The resistive memory includes an top electrode and a bottom electrode, and a combination of a plurality of switching layers and defective layers interposed between the top electrode and the bottom electrode, wherein, the top electrode and the bottom electrode are respectively contacted with a switching layer (a film such as Ta | 03-21-2013 |
20130069126 | GERMANIUM-BASED NMOS DEVICE AND METHOD FOR FABRICATING THE SAME - An embodiment of the invention provides a germanium-based NMOS device and a method for fabricating the same, which relates to fabrication process technology of an ultra-large-scale-integrated (ULSI) circuit. The germanium-based NMOS device has two dielectric layer interposed between a metal source/drain and a substrate. The bottom dielectric layer includes a dielectric material having a high pinning coefficient S such as hafnium oxide, silicon nitride, hafnium silicon oxide or the like, and the top dielectric layer includes a dielectric material having a low conduction band offset ΔE | 03-21-2013 |
20130075701 | PROGRAMMABLE ARRAY OF SILICON NANOWIRE FIELD EFFECT TRANSISTOR AND METHOD FOR FABRICATING THE SAME - The present invention discloses a hexagonal programmable array based on a silicon nanowire field effect transistor and a method for fabricating the same. The array includes a nanowire device, a nanowire device connection region and a gate connection region, wherein, the nanowire device has a cylinder shape, and includes a silicon nanowire channel, a gate dielectric layer, and a gate region, the nanowire channel being surrounded by the gate dielectric layer, and the gate dielectric layer being surrounded by the gate region; the nanowire devices are arranged in a hexagon shape to form programming unit, the nanowire device connection region is a connection node of three nanowire devices and secured to a silicon supporter. The present invention can achieve a complex control logic of interconnections and is suitable for a digital/analog and a mixed-signal circuit having a high integration degree and a high speed. | 03-28-2013 |
20130099300 | Floating Gate Structure of Flash Memory Device and Method for Fabricating the Same - The present invention discloses a floating gate structure of a flash memory device and a method for fabricating the same, which relates to a nonvolatile memory in a manufacturing technology of an ultra-large-scaled integrated circuit. In the invention, by modifying a manufacturing of a floating gate in the a standard process for the flash memory, that is, by adding three steps of deposition, two steps of etching and one step of CMP, an I-shaped floating gate is formed. In addition to these steps, all the other steps are the same as those of the standard process for the flash memory process. By the invention, a coupling ratio may be improved effectively and a crosstalk between adjacent devices may be lowered, without adding additional photomasks and barely increasing a process complexity, which are very important to improve programming speed and reliability. | 04-25-2013 |
20130103351 | Method for Predicting Reliable Lifetime of SOI Mosfet Device - Disclosed herein is a method for predicting a reliable lifetime of a SOI MOSFET device. The method comprises: measuring a relationship of a gate resistance of the SOI MOSFET device varying as a function of a temperature at different wafer temperatures; performing a lifetime accelerating test on the SOI MOSFET 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 SOI MOSFET device under a bias. The embodiment of the invention prevents the self-heating effect from affecting the SOI MOSFET device in a practical logic circuit or in an AC analog circuit, which leads to a more precise prediction result. | 04-25-2013 |
20130119445 | CMOS DEVICE FOR REDUCING RADIATION-INDUCED CHARGE COLLECTION AND METHOD FOR FABRICATING THE SAME - 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. | 05-16-2013 |
20130130503 | METHOD FOR FABRICATING ULTRA-FINE NANOWIRE - Disclosed herein is a method for fabricating an ultra-fine nanowire by combining a trimming process and a mask blocking oxidation process. The ultra-thin nanowire is fabricated by a combination of performing a trimming process on a mask to reduce a width of the mask and blocking an oxidation through the mask. A diameter of the floated ultra-thin nanowire fabricated by the method is controlled to 20 nm below by a thickness of a deposited silicon oxide film, a width of the silicon oxide nanowire after trimming, and a time and a temperature for performing a wet oxidation process. Also, since a speed of the wet oxidation process is faster, the width of the nanowire obtained by a conventional photolithography is reduced faster. Moreover, when fabricating an ultra-thin nanowire by using the method, the cost is reduced and it is more feasible to be implemented. | 05-23-2013 |
20130141183 | DIRECTIONAL COUPLER INTEGRATED BY CMOS PROCESS - A directional coupler is disclosed integrated on a single chip and an integrated circuit based on a standard CMOS process and relates to a field of radio frequency communication. In exemplary implementations, by using a standard CMOS process technology, the directional coupler integrated by a CMOS process is formed by a coil winded by a upper layer of metal lines, a coil winded by a lower layer of metal lines, two tuning capacitor array, and a matching resistor. Two terminals of the coil are a direct terminal and an input terminal; two terminals of the coil are a coupled terminal and an isolation terminal; the terminals of the coils and are intersected at 90°; the coil is winded by an upper metal layer and the coil is winded by a lower metal layer. Further, the insertion loss is low and the isolation degree is large. | 06-06-2013 |
20130161757 | CMOS Device for Reducing Charge Sharing Effect and Fabrication Method Thereof - 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. The present invention can reduce the charge sharing effect due to heavy ions by using a feature that the defect states in the porous silicon trap carriers, the formation of a shallow trench isolation (STI) region and a isolation region underneath only needs one time photolithography, and the process is simple, so that radioresistance performance of an integrated circuit may be greatly increased. | 06-27-2013 |
20130168759 | FIELD EFFECT TRANSISTOR WITH A VERTICAL CHANNEL AND FABRICATION METHOD THEREOF - Disclosed herein is a field effect transistor with a vertical channel and a fabrication method thereof. A channel region of the field effect transistor is a circular ring-shaped Si platform, which is formed over a substrate and perpendicular to the substrate; a source, which is made of polysilicon, is located at an upper end of the Si platform; a drain is disposed at an outside of a lower end of the circular ring-shaped Si platform; a gate is placed on an outer side surface of the circular ring-shaped Si platform; and an inside of the circular ring-shaped Si platform is filled with a dielectric material. In comparison with the conventional vertical structure MOSFET with a Si platform, the circular ring-shaped structure field effect transistor according to the invention can effectively suppress the short channel effect and improve the device performance. | 07-04-2013 |
20130214810 | METHOD FOR TESTING DENSITY AND LOCATION OF GATE DIELECTRIC LAYER TRAP OF SEMICONDUCTOR DEVICE - Proposed is a method for testing the density and location of a gate dielectric layer trap of a semiconductor device. The testing method tests the trap density and two-dimensional trap location in the gate dielectric layer of a semiconductor device with a small area (the effective channel area is less than 0.5 square microns) using the gate leakage current generated by a leakage path. The present invention is especially suitable for testing a device with an ultra-small area (the effective channel area is less than 0.05 square microns). The present method can obtain trap distribution scenarios of the gate dielectric layer in the case of different materials and different processes. In the present method, the device requirements are simple, the testing structure is simple, the testing cost is low, the testing is rapid and the trap distribution of the gate dielectric layer of the device can be obtained within a short time, which is suitable for large batches of automatic testing and is especially suitable for process monitoring and finished product quality detection during the manufacture of ultra-small semiconductor devices. | 08-22-2013 |
20130217199 | METHOD FOR FABRICATING RESISTIVE MEMORY DEVICE - The present invention discloses a method for fabricating a resistive memory, including: fabricating a bottom electrode over a substrate; partially oxidizing a metal of the bottom electrode through dry-oxygen oxidation or wet-oxygen oxidation to form a metal oxide with a thickness of 3 nm to 50 nm as a resistive material layer; finally fabricating a top electrode over the resistive material layer. The present invention omits a step of depositing a resistive material layer in a conventional method, so as to greatly reduce the process complexity. Meanwhile, a self alignment between the resistive material layer and the bottom electrode can be realized. A full isolation between devices may be ensured so as to obviate the parasite effects occurred in the conventional process methods. Meanwhile, the actual area and designed area of the device are ensured to be consistent. | 08-22-2013 |
20130309875 | INTERFACE TREATMENT METHOD FOR GERMANIUM-BASED DEVICE - Disclosed herein is an interface treatment method for germanium-based device, which belongs to the field of manufacturing technologies of ultra large scaled integrated (ULSI) circuits. In the method, the natural oxide layer on ther surface of the germanium-based substrate is removed by using a concentrated hydrochloric acid solution having a mass percentage concentration of 15%˜36%, and dangling bonds of the surface are performed a passivation treatment by using a diluted hydrochloric acid solution having a mass percentage concentration of 5%˜10% so as to form a stable passivation layer on the surface. This method makes a good foundation for depositing a high-K (high dielectric constant) gate dielectric on the surface of the germanium-based substrate after cleaning and passivating, enhances quality of the interface between the gate dielectric and the substrate, and improves the electrical performance of germanium-based MOS device. | 11-21-2013 |
20140017870 | Method for Inhibiting Programming Disturbance of Flash Memory - Disclosed herein is a method for inhibiting a programming disturbance of a flash memory, which relates to a technical field of a non-volatile memory in ultra-large-scale integrated circuit fabrication technologies. In the present invention, an dopant gradient of a PN junction between a substrate and a drain is reduced by adding a step of performing an angled ion implantation of donor dopants into a standard process for a flash memory, so that an electric field of the PN junction between the substrate and the drain is reduced, and consequently the programming disturbance is inhibited. Meanwhile, a dopant gradient of the PN junction between a channel and the drain is maintained, so that an electric field of the PN junction between the channel and the drain, which is necessary for programming, is maintained, and thus the programming efficiency and the programming speed can be ensured. The programming disturbance can be effectively inhibited without increasing numbers of masks used for photolithography according to the invention, thus the present invention is significantly advantageous to the improvement of the flash memory reliability. | 01-16-2014 |
20140117465 | GE-BASED NMOS DEVICE AND METHOD FOR FABRICATING THE SAME - 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 (GeO | 05-01-2014 |
20140145139 | TRANSPARENT FLEXIBLE RESISTIVE MEMORY AND FABRICATION METHOD THEREOF - The present invention discloses a transparent flexible resistive memory and a fabrication method thereof. The transparent flexible resistive memory includes a transparent flexible substrate, a memory unit with a MIM capacitor structure over the substrate, wherein a bottom electrode and a top electrode of the memory unit are transparent and flexible, and an intermediate resistive layer is a transparent flexible film of poly(p-xylylene). Poly(p-xylylene) has excellent resistive characteristics. In the device, the substrate, the electrodes and the intermediate resistive layer are all formed of transparent flexible material so that a completely transparent flexible resistive memory which can be used in a transparent flexible electronic system is obtained. | 05-29-2014 |
20140203324 | A STRIP-SHAPED GATE-MODULATED TUNNELING FIELD EFFECT TRANSISTOR AND A PREPARATION METHOD THEREOF - The present invention discloses a strip-shaped gate-modulated tunneling field effect transistor and a preparation method thereof, belonging to a field of field effect transistor logic device and the circuit in CMOS ultra large scale integrated circuit (ULSI). The tunneling field effect transistor includes a control gate, a gate dielectric layer, a semiconductor substrate, a highly-doped source region and a highly-doped drain region, where the highly-doped source region and the highly-doped drain region lie on both sides of the control gate, respectively, the control gate has a strip-shaped structure with a gate length greater than a gate width, and at one side thereof is connected to the highly-doped drain region and at the other side thereof extends laterally into the highly-doped source region; a region located below the control gate is a channel region; and the gate width of the control gate is less than twice width of a source depletion layer. The device modulates the source-side tunneling junction by using the strip-shaped gate structure, achieves the effect equivalent to that the source junction has a steep doping concentration gradient, and improves the TFET device performance; and the preparation method thereof is simple. | 07-24-2014 |
20140220748 | METHOD FOR FABRICATING COMPLEMENTARY TUNNELING FIELD EFFECT TRANSISTOR BASED ON STANDARD CMOS IC PROCESS - Disclosed herein is a method for fabricating a complementary tunneling field effect transistor based on a standard CMOS IC process, which belongs to the field of logic devices and circuits of field effect transistors in ultra large scaled integrated (ULSI) circuits. In the method, an intrinsic channel and body region of a TFET are formed by means of complementary P-well and N-well masks in the standard CMOS IC process to form a well doping, a channel doping and a threshold adjustment by implantation. Further, a bipolar effect in the TFET can be inhibited via a distance between a gate and a drain on a layout so that a complementary TFET is formed. In the method according to the invention, the complementary tunneling field effect transistor (TFET) can be fabricated by virtue of existing processes in the standard CMOS IC process without any additional masks and process steps. | 08-07-2014 |
20140268988 | RESISTIVE MEMORY CELL - The present invention discloses a resistive memory cell, including a unipolar type RRAM and a MOS transistor as a selection transistor serially connected to the unipolar type RRAM, wherein the MOS transistor is fabricated over a partial depletion SOI substrate and provides a large current for program and erase of the RRAM by using an intrinsic floating effect of the SOI substrate. The present invention utilizes a floating effect of a SOI device, in which under the same width/length ratio, a MOS transistor over a SOI substrate can provide larger source/drain current than a MOS transistor over a bulk silicon, so that the area occupied by the selection transistor is reduced, which is advantageous to the integration of the RRAM array. | 09-18-2014 |
20140306173 | RESISTIVE MEMORY AND METHOD FOR FABRICATING THE SAME - A resistive memory having a leakage inhibiting characteristic and a method for fabricating the same, which can suppress a sneak current in a large scaled crossing array of a RRAM. A memory cell forming the resistive memory comprises a lower electrode, a first semiconductor-type oxide layer, a resistive material layer, a second semiconductor-type oxide layer and an upper electrode which are sequentially stacked. Each of the semiconductor-type oxide layers may be a semiconductor-type metal oxide or a semiconductor-type non-metal oxide. The sneak current may be effectively reduced by means of a Schottky barrier formed between the semiconductor-type oxide layer and the metal electrode, the fabrication process is easy to be implemented, and a high device integration degree can be achieved. | 10-16-2014 |
20150014765 | RADIATION RESISTANT CMOS DEVICE AND METHOD FOR FABRICATING THE SAME - 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. | 01-15-2015 |
20150021539 | RESISTIVE MEMORY WITH SMALL ELECTRODE AND METHOD FOR FABRICATING THE SAME - Systems and methods are disclosed involving a resistive memory with a small electrode, relating to the field of semiconductor resistive memory in ULSI. An illustrative resistive memory may include an Al electrode layer, a SiO | 01-22-2015 |
20150024561 | METHOD FOR FABRICATING A FINFET IN A LARGE SCALE INTEGRATED CIRCUIT - Systems and methods of fabricating a FinFET in large scale integrated circuit are disclosed. One illustrative method relates to a dummy gate process, wherein the fin structure is only formed in the gate electrode region by performing a photolithography process and an etching of a first dummy gate on a flat STI surface using chemical mechanical polishing, forming drain and source regions, depositing a medium dielectric layer, polishing the medium dielectric layer till the top of the first dummy gate is exposed through the chemical mechanical polishing process again, removing the dummy gate material via a dry etching and a wet etching, and continuously etching the STI dielectric layer with the hard mask formed by the medium dielectric layer, thereafter performing the deposition of real gate dielectric and gate electrode material to complete the device structure. | 01-22-2015 |
20150031188 | METHOD FOR ISOLATING ACTIVE REGIONS IN GERMANIUM-BASED MOS DEVICE - 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. | 01-29-2015 |
20150048313 | STRIP-SHAPED GATE TUNNELING FIELD EFFECT TRANSISTOR WITH DOUBLE-DIFFUSION AND A PREPARATION METHOD THEREOF - The present invention discloses a strip-shaped gate-modulated tunneling field effect transistor with double-diffusion and a preparation method thereof, belonging to a field of CMOS field effect transistor logic device and the circuit. The tunneling field effect transistor includes a semiconductor substrate, a highly-doped source region, a highly-doped drain region, a double-diffusion source region, a gate dielectric layer, and a control gate, wherein the control gate has a strip-shaped structure with a gate length greater than a gate width, and at one side thereof is connected to the highly-doped drain region and at the other side thereof extends laterally into the highly-doped source region; a region located below the control gate is a channel region; the gate width of the control gate is less than twice width of a source depletion layer; the double-diffusion region has the same doping region as the highly-doped source region and the double-diffusion region has the same doping type as the highly-doped drain region; and the channel region located below a portion of the control gate portion in the highly-doped source region has double-diffusion source doped impurities. The TFET device according to the invention improves its performance, and the preparation method thereof is simple. | 02-19-2015 |