Abstract: A Junction Field Effect Transistor (JFET) can be fabricated with a well region that include a channel region having an average dopant concentration substantially less the average doping concentration of the remaining portions of the well region. The lower average doping concentration of channel region compared to the remaining portions of the well region reduces the pinch-off voltage of the JFET.

Abstract: A complimentary metal oxide semiconductor and a method of manufacturing the same using a self-aligning process to form one of the stacks of device. The method includes depositing an oxide layer over a portion of a metal layer over an nFET region of a CMOS structure and etching the metal layer over a pFET region of the CMOS structure. The method further includes etching at the oxide layer over the nFET region and forming gate structures over the nFET region and pFET region.

Abstract: A CMOS image sensor and a method for manufacturing the same improves signal efficiency by reducing a dark signal, and includes a substrate having a first conductive type comprising an image area and a circuit area, a STI isolation layer in the substrate for electrical isolation within the circuit area, and a field oxide in the substrate for electrical isolation within the image area.

Abstract: Example embodiments relate to an image sensor and a fabrication method thereof, capable of reducing dark current and a fabrication method thereof. The image sensor may include a semiconductor substrate including an active region defined by an isolation layer, a photoelectric-conversion region and a charge-movement-prevention region formed at an interface between the photoelectric-conversion region and the isolation layer.

Abstract: A method of fabricating a CMOS integrated circuit includes the steps of providing a substrate having a semiconductor surface, forming a gate dielectric and a plurality of gate electrodes thereon in both NMOS and PMOS regions using the surface. A multi-layer offset spacer stack including a top layer and a compositionally different bottom layer is formed and the multi-layer spacer stack is etched to form offset spacers on sidewalls of the gate electrodes. The transistors designed to utilize a thinner offset spacer are covered with a first masking material, and transistors designed to utilize a thicker offset spacer are patterned and first implanted. At least a portion of the top layer is removed to leave the thinner offset spacers on sidewalls of the gate electrodes. The transistors designed to utilize the thicker offset spacer are covered with a second masking material, and the transistors designed to utilize the thinner offset spacer are patterned and second implanted.

Abstract: A method and system for providing a twin well in a semiconductor device is described. The method and system include providing at least one interference layer and providing a first mask that covers a first portion of the semiconductor device and uncovers a second portion of the semiconductor device. The first and second portions of the semiconductor device are adjacent. The method and system also include implanting a first well in the second portion of the semiconductor device after the first mask is provided. The method and system also include providing a second mask. The interference layer(s) are configured such that energy during a blanket exposure develops the second mask that uncovers the first portion and covers the second portion of the semiconductor device. The method and system also include implanting a second well in the first portion of the semiconductor device after the second mask is provided.

Abstract: An electronic device can include a first transistor structure including a first gate electrode surrounded by a first sidewall spacer having a first stress and a second transistor structure including a second gate electrode surrounding a second sidewall spacer having second stress. The first sidewall spacer is an only sidewall spacer surrounding the first gate electrode or a closer sidewall spacer as compared to any other sidewall spacer that surrounds the first gate electrode and the second sidewall spacer is an only sidewall spacer surrounding the second gate electrode or a closer sidewall spacer as compared to any other sidewall spacer that surrounds the second gate electrode, wherein the first stress has a lower value as compared to the second stress. More than one process can be used to form the electronic device.

Abstract: A method of forming an electronic device is provided that includes selectively implanting ions into a workpiece, wherein ions are implanted into a first region of the workpiece that includes a semiconductor material, while substantially none of the ions are implanted into a second region of the workpiece that also includes a semiconductor material. The method further includes depositing a metal-containing film over the first region and the second region after selectively implanting, and then reacting the metal-containing film with the semiconductor material to form a first metal-semiconductor film within the first region and a second metal-semiconductor film within the second region. The first metal-semiconductor film has a first thickness and the second metal-semiconductor film has a second thickness that is different from the first thickness.

Abstract: The present invention provides a technique for forming differently stressed contact etch stop layers, wherein sidewall spacers are removed prior to the formation of the contact etch stop layers. During the partial removal of respective contact etch stop layers, a corresponding etch stop layer regime is used to substantially avoid any unwanted stress-inducing material residuals, thereby significantly enhancing the stress transfer mechanism.

Abstract: A method for manufacturing a semiconductor device is provided. The method includes forming a negative photoresist layer on a semiconductor substrate, forming a photoresist pattern on the negative photoresist layer, forming a well region in the semiconductor substrate, implanting ions into the semiconductor substrate, using the photoresist pattern as a mask, such that the ions are implanted into the well region, removing the photoresist pattern, and forming a gate region and a source/drain region on the semiconductor substrate.

Abstract: A method for making a semiconductor device structure includes producing a substrate having formed thereon a gate with spacers, respective source and drain regions adjacent to the gate and an; disposing a first metallic layer on the gate with spacers, and the source and drain regions, disposing a second metallic layer on the first metallic layer; doping the first metallic layer with a first dopant through a portion of the second metal layer disposed over the second gate with spacers; and then heating the intermediate structure to a temperature and for a time sufficient to form a silicide of the first metallic layer. This first layer is, for example, Ni while the second layer is, for example, TiN.

Abstract: A semiconductor device having a high-K gate dielectric layer includes a p-type well that is formed in an upper layer of a silicon substrate. Arsenic ions are implanted into an extreme surface layer of the p-type well and a heat treatment is performed to form a p-type low-concentration layer. A HfAlOx film and a polycrystalline silicon layer are laminated on the substrate. A gate electrode is formed by patterning the polycrystalline silicon layer. After a n-type extension region is formed by implanting arsenic ions by using the gate electrode as a mask, sidewall spacers are formed on sides of the gate electrode. Arsenic ions are implanted by using the sidewall spacers and the gate electrode as masks, whereby n-type source/drain regions are formed.

Abstract: This patent specification describes methods for fabricating semiconductor device having a plurality of well structures including a triple-well structure.

Abstract: Structures, systems and methods for transistors having gates with variable work functions formed by atomic layer deposition are provided. One transistor embodiment includes a first source/drain region, a second source/drain region, and a channel region therebetween. A gate is separated from the channel region by a gate insulator. The gate includes a ternary metallic conductor formed by atomic layer deposition.

Abstract: An N-channel transistor includes: an N-type source region, a gate electrode, a P-type body region, an N-type drain offset region, and a drain contact region, which is an N-type drain region. The transistor further includes a gate insulating film that has a thin oxide silicon film (a thin film portion) and a LOCOS film (a thick film portion). The body region has an impurity profile in which the concentration reaches a maximum value near the surface and decreases with distance from the surface. The drain offset region has an impurity profile that has an impurity-concentration peak in a deep portion located a certain depth-extent below the lower face of the LOCOS film.

Abstract: Disclosed is a method for forming a gate of a semiconductor device capable of preventing a bridge from being created between adjacent gates due to a nitride polymer. The method includes the steps of forming a gate oxide film, a gate poly-Si film, and a gate W film successively on a semiconductor substrate; forming a pure SiN film and an oxide-rich SiN film successively on the gate W film as hard mask films; forming an oxide-rich SiON film on the oxide-rich SiN film as an anti-reflective coating film; patterning the oxide-rich SiON film, the oxide-rich SiN film, and the pure SiN film into the shape of a gate; and etching the gate W film, the gate poly-Si film, and the gate oxide film successively using the patterned pure SiN film as an etching barrier.

Abstract: The present invention discloses a triple well structure, which includes a substrate of a first conductive type, a deep buried well of a second conductive type, a well of a first conductive type, a well ring of a second conductive type, and a well ring of a first conductive type. The deep buried well of the second conductive type is in the substrate. The well of the first conductive type is disposed over the deep buried well of the second conductive type in the substrate. The well ring of the second conductive type surrounds the well of the first conductive type. The well ring of the first conductive type is between the well of the first conductive type and the well ring of the second conductive type.

Abstract: According to the embodiments to the present disclosure, the process of making a dual strained channel semiconductor device includes integrating strained Si and compressed SiGe with trench isolation for achieving a simultaneous NMOS and PMOS performance enhancement. As described herein, the integration of NMOS and PMOS can be implemented in several ways to achieve NMOS and PMOS channels compatible with shallow trench isolation.

Abstract: The present invention is generally directed to a method of forming a p-well in an integrated circuit device. In one illustrative embodiment, the method comprises forming a first layer of epitaxial material above an active layer of a substrate, forming a first doped region in the first layer of epitaxial material, forming a second layer of epitaxial material above the first layer of epitaxial material, forming a second doped region in the second layer of epitaxial material, and performing at least one heat treating process.

Abstract: The present invention facilitates semiconductor fabrication by providing methods of fabrication that apply tensile strain to channel regions of devices while mitigating unwanted dopant diffusion, which degrades device performance. Source/drain regions are formed in active regions of a PMOS region (102). A first thermal process is performed that activates the formed source/drain regions and drives in implanted dopants (104). Subsequently, source/drain regions are formed in active regions of an NMOS region (106). Then, a capped poly layer is formed over the device (108). A second thermal process is performed (110) that causes the capped poly layer to induce strain into the channel regions of devices. Because of the first thermal process, unwanted dopant diffusion, particularly unwanted p-type dopant diffusion, during the second thermal process is mitigated.

Abstract: A semiconductor integrated circuit includes an n-channel MOS transistor and a p-channel MOS transistor formed respectively in first and second device regions of a substrate, the n-channel MOS transistor including a first gate electrode carrying sidewall insulation films on respective sidewall surfaces thereof, the p-channel MOS transistor including a second gate electrode carrying sidewall insulation films on respective sidewall surfaces thereof, wherein there is provided a stressor film on the substrate over the first and second device regions such that the stressor film covers the first gate electrode including the sidewall insulation films thereof and the second gate electrode including the sidewall insulation films thereof, wherein the stressor film has a decreased film thickness in the second device region at least in the vicinity of a base part of the second gate electrode.

Abstract: The present invention discloses a triple well structure, which includes a substrate of a first conductive type, a deep buried well of a second conductive type, a well of a first conductive type, a well ring of a second conductive type, and a well ring of a first conductive type. The deep buried well of the second conductive type is in the substrate. The well of the first conductive type is disposed over the deep buried well of the second conductive type in the substrate. The well ring of the second conductive type surrounds the well of the first conductive type. The well ring of the first conductive type is between the well of the first conductive type and the well ring of the second conductive type.

Abstract: A p-channel MOSFET (1) includes a semiconductor substrate (2), an epitaxial region (3), a second diffusion region (6), and a drain region. The epitaxial region (3) is formed on the upper surface of the semiconductor substrate (2). The second diffusion region (6) is formed in a predetermined upper surface area of the epitaxial region (3). The second diffusion region (6) has a central portion (6a) and a peripheral portion (6b). The central portion (6a) is formed substantially at the center of the epitaxial region (3) and formed thicker than the peripheral portion (6b). The peripheral portion (6b) is formed in an annular shape so as to surround the central portion (6a). The drain region (7) is formed in an upper surface area of the central portion (6a) of the second diffusion region (6).