摘要:
A method of making N-channel and P-channel IGFETs is disclosed. The method includes providing a semiconductor substrate with N-type and P-type active regions, forming a gate material over the N-type and P-type active regions, forming a first masking layer over the gate material, wherein the first masking layer includes an opening above a first portion of the gate material over the P-type active region, and the first masking layer covers a second portion of the gate material over the N-type active region, introducing an N-type dopant into the first portion of the gate material without introducing the N-type dopant into the second portion of the gate material, applying a thermal cycle to drive-in and activate the N-type dopant in the first portion of the gate material before introducing any doping into the second portion of the gate material, before introducing any source/drain doping into the N-type active region, and before introducing any source/drain doping into the P-type active region, forming a second masking layer over the gate material, wherein the second masking layer covers portions of the first and second portions of the gate material, applying an etch to form first and second gates from unetched portions of the first and second portions of the gate material, respectively, and forming an N-type source and drain in the P-type active region and forming a P-type source and drain in the N-type active region. Advantageously, a dopant in the gate for the N-channel IGFET can be driven-in and activated at a relatively high temperature without subjecting any source/drain doping to this temperature.
摘要:
A nitrogen implanted region formed substantially below and substantially adjacent to a source/drain region of an IGFET forms a liner to retard the diffusion of the source/drain dopant atoms during a subsequent heat treatment operation such as an annealing step. The nitrogen liner may be formed by implantation of nitrogen to a given depth before the implantation of source/drain dopant to a lesser depth. Nitrogen may also be introduced into regions of the IGFET channel region beneath the gate electrode for retarding subsequent lateral diffusion of the source/drain dopant. Such nitrogen introduction may be accomplished using one or more angled implantation steps, or may be accomplished by annealing an implanted nitrogen layer formed using a perpendicular implant aligned to the gate electrode. The liner may be formed on the drain side of the IGFET or on both source and drain side, and may be formed under a lightly-doped region or under a heavily-doped region of the drain and/or source. Such a liner is particularly advantageous for boron-doped source/drain regions, and may be combined with N-channel IGFETs formed without such liners.
摘要:
An IGFET with a gate electrode and a source contact in a trench is disclosed. The IGFET includes a trench with opposing sidewalls and a bottom surface in a semiconductor substrate, a gate insulator on the bottom surface, a gate electrode on the gate insulator, a source contact on the bottom surface, insulative spacers between the gate electrode, the source contact and the sidewalls, and a source and drain adjacent to the bottom surface. Advantageously, the source contact overlaps the trench, thereby improving packing density.
摘要:
A method of establishing a differential threshold voltage during the fabrication of first and second IGFETs having like conductivity type is disclosed. A dopant is introduced into the gate electrode of each transistor of the pair. The dopant is differentially diffused into respective channel regions to provide a differential dopant concentration therebetween, which results in a differential threshold voltage between the two transistors. One embodiment includes introducing a diffusion-retarding material, such as nitrogen, into the first gate electrode before the dopant is diffused into the respective channel regions, and without introducing a significant amount of the diffusion-retarding material into the second gate electrode. Advantageously, a single dopant implant can provide both threshold voltage values. The two threshold voltages may be chosen to provide various combinations of enhancement mode and depletion mode IGFETs.
摘要:
An IGFET with a gate electrode and a source contact in a trench is disclosed. The IGFET includes a trench with opposing sidewalls and a bottom surface in a semiconductor substrate, a gate insulator on the bottom surface, a gate electrode on the gate insulator, a source contact on the bottom surface, insulative spacers between the gate electrode, the source contact and the sidewalls, and a source and drain adjacent to the bottom surface. A method of forming an IGFET includes forming a trench with first and second opposing sidewalls and a bottom surface in a substrate, forming disposable spacers on the bottom surface, forming a gate insulator material on the bottom surface between the disposable spacers, depositing a gate electrode material on the gate insulator material and disposable spacers, polishing the gate electrode material and then anisotropically etching a lateral portion of the gate electrode material and gate insulator material to form the gate electrode and gate insulator, removing the disposable spacers, forming a first insulative spacer adjacent to the first sidewall, a second insulative spacer adjacent to the gate electrode and second sidewall, and a third insulative spacer adjacent to the gate electrode such that a contact portion of the bottom surface between the first and third insulative spacers is exposed, forming a source and drain in the substrate and adjacent to the bottom surface, and forming source and drain contacts such that the source contact is electrically coupled to the source at the contact portion of the bottom surface and the drain contact is electrically coupled to the drain at the top surface of the substrate. Advantageously, the source contact overlaps the trench, thereby improving packing density.
摘要:
A resistor is formed between devices in an integrated circuit by forming a patterned trench in an intralayer dielectric (ILD) deposited over the devices, filling the trench with polysilicon and planarizing the polysilicon. The resistance of the resistor is defined by determining and selecting the size and form of the trench including the width, length, depth and orientation of the trench. In some embodiments, the resistance of the resistor is also controlled by adding selected amounts and species of dopants to the polysilicon. In some embodiments, the resistance is controlled by directly saliciding the polysilicon in the trench.
摘要:
A method of forming a contact hole in an interlevel dielectric layer using dual etch stops includes the steps of providing a semiconductor substrate, forming a gate over the substrate, forming a source/drain region in the substrate, providing a source/drain contact electrically coupled to the source/drain region, forming an interlevel dielectric layer that includes first, second and third dielectric layers over the source/drain contact, forming an etch mask over the interlevel dielectric layer, applying a first etch which is highly selective of the first dielectric layer with respect to the second dielectric layer through an opening in the etch mask using the second dielectric layer as an etch stop, thereby forming a first hole in the first dielectric layer that extends to the second dielectric layer without extending to the third dielectric layer, applying a second etch which is highly selective of the second dielectric layer with respect to the third dielectric layer through the opening in the etch mask using the third dielectric layer as an etch stop, thereby forming a second hole in the second dielectric layer that extends to the third dielectric layer without extending to the source/drain contact, and applying a third etch which is highly selective of the third dielectric layer with respect to the source/drain contact through the opening in the etch mask, thereby forming a third hole in the third dielectric layer that extends to the source/drain contact, wherein the first, second and third holes in combination provide the contact hole. In this manner, the contact hole is formed in the interlevel dielectric without any appreciable gouging of the underlying materials.
摘要:
A composite gate electrode layer incorporates a diffusion-retarding barrier layer disposed at the bottom of the gate electrode layer to reduce the amount of dopant which diffuses into the gate dielectric layer from the gate electrode layer. A lower nitrogen-containing gate electrode layer provides a diffusion-retarding barrier layer against dopant diffusion into the gate dielectric layer disposed therebelow, and an upper gate electrode layer is formed upon the lower layer and is doped to form a highly conductive layer. Together the first and second gate electrode layers form a composite gate electrode layer which incorporates a diffusion-retarding barrier layer adjacent to the underlying gate dielectric layer. The barrier layer may be formed by annealing a first polysilicon layer in a nitrogen-containing ambient, such as N.sub.2, NO, N.sub.2 O, and NH.sub.3, by implanting a nitrogen-containing material, such as elemental or molecular nitrogen, into a first polysilicon layer, and by in-situ depositing a nitrogen-doped first polysilicon layer. Diffusion of dopants into the gate dielectric layer may be retarded, as most dopant atoms are prevented from diffusing from the composite gate electrode layer at all. In addition, the nitrogen concentration within the gate dielectric layer, particularly at or near the substrate interface, may be maintained at lower concentrations than otherwise necessary to prevent dopant diffusion into the underlying substrate. The present invention is particularly well suited to thin gate dielectrics, such as a those having a thickness less than approximately 60 .ANG. when using a p-type dopant, such as boron.
摘要:
An integrated circuit fabrication process is provided in which an elevated doped polysilicon structure may be formed. The elevated structure may serve as a junction area of a transistor formed entirely within and upon the elevated polysilicon. The elevated structure frees up space within the lower level substrate for additional transistors and/or lateral interconnect, a benefit of which is to promote higher packing density within the integrated circuit. A transistor is provided which includes a gate conductor spaced between a pair of junctions. A primary interlevel dielectric is deposited across the transistor. A polysilicon structure is formed within a select portion of the upper surface of the primary interlevel dielectric. The polysilicon structure is a spaced distance above and a lateral distance from the transistor. A dopant is implanted into the polysilicon structure. A secondary interlevel dielectric is deposited across the primary interlevel dielectric and the doped polysilicon structure. Select portions of the primary and secondary interlevel dielectrics are then removed to expose one of the junctions and a portion of the doped polysilicon structure arranged proximate this junction. An interconnect is formed contiguously between the junction and the polysilicon structure by depositing a conductive material within the removed portions.
摘要:
In an IGFET device having at least one source/drain region with a lightly-doped sub-region proximate a channel region, the source/drain regions are formed by first implanting ions with parameters to form lightly-doped source/drain regions. A high density plasma deposition provides at least one spacer having preselected characteristics. As a result of the spacer characteristics, an ion implantation with parameters to form normally-doped source/drain regions is shadowed by the spacer. A portion of the source/drain region shadowed by the spacer results in a lightly-doped source/drain sub-region proximate the channel region. According to a second embodiment of the invention, the ion implantation resulting in the lightly-doped source/drain regions is eliminated. Instead, the spacer(s) formed by the high density plasma deposition and subsequent etching process only partially shadows the ion implantation that would otherwise result in normal doping of the source/drain regions. The parameters of the spacer(s) resulting from the high density plasma deposition and subsequent etching process result in a lightly-doped source/drain sub-region proximate the channel region. The shadowing of the spacer decreases with distance from the gate structure and results in a normal doping level for the portion of the source/drain terminal not shadowed by the spacer.