Abstract: The present disclosure relates to a back-side illuminated CMOS image sensor (BSI CIS). In some embodiments, the BSI CSI has a semiconductor substrate with a front-side and a back-side. A plurality of photodetectors are located within the front-side of the semiconductor substrate. An implantation region is located within the semiconductor substrate at a position separated from the plurality of photodetectors. The implantation region is disposed below the plurality of photodetectors and has a non-uniform doping concentration along a lateral plane parallel to the back-side of the semiconductor substrate. The non-uniform doping concentration allows for the BSI CSI to achieve a small total thickness variation (TTV) between one or more photodetectors and a back-side of a thinned semiconductor substrate that provides for good device performance.

Abstract: Provided is a method of transforming an integrated circuit (IC) pattern into one or more patterns suitable for subsequent processing, such as mask fabrication. The method includes receiving an IC pattern that has an arbitrary shape, and using a computer, deriving an approximation IC pattern, wherein the approximation IC pattern is in a shape that is a user-defined fabrication-friendly shape, such as a rectangle or an ellipse. The method further includes calculating a pattern approximation error between the IC pattern and the approximation IC pattern. The method further includes checking whether the pattern approximation error is less than a user-defined threshold. If it is, the method further includes outputting the approximation IC pattern for subsequent fabrication. Otherwise, the method further includes splitting the IC pattern into a plurality of subparts, and recursively transforming each of the plurality of subparts.

Abstract: A device includes a first and a second package component. A metal trace is disposed on a surface of the first package component. The metal trace has a lengthwise direction. The metal trace includes a portion having an edge, wherein the edge is not parallel to the lengthwise direction of the metal trace. The second package component includes a metal pillar, wherein the second package component is disposed over the first package component. A solder region bonds the metal pillar to the metal trace, wherein the solder region contacts a top surface and the edge of the portion of the metal trace.

Abstract: A method for forming a semiconductor structure includes providing a semiconductor substrate including a first region and a second region; and forming a first and a second metal-oxide-semiconductor (MOS) device. The step of forming the first MOS device includes forming a first silicon germanium layer over the first region of the semiconductor substrate; forming a silicon layer over the first silicon germanium layer; forming a first gate dielectric layer over the silicon layer; and patterning the first gate dielectric layer to form a first gate dielectric. The step of forming the second MOS device includes forming a second silicon germanium layer over the second region of the semiconductor substrate; forming a second gate dielectric layer over the second silicon germanium layer with no substantially pure silicon layer therebetween; and patterning the second gate dielectric layer to form a second gate dielectric.

Abstract: A method for forming a field-effect transistor with a raised drain structure is disclosed. The method includes forming a frustoconical source by etching a semiconductor substrate, the frustoconical source protruding above a planar surface of the semiconductor substrate; forming a transistor gate, a first portion of the transistor gate surrounding a portion of the frustoconical source and a second portion of the gate configured to couple to a first electrical contact; and forming a drain having a raised portion configured to couple to a second electrical contact and located at a same level above the planar surface of the semiconductor substrate as the second portion of the transistor gate. A semiconductor device having a raised drain structure is also disclosed.

Abstract: The present disclosure provides a semiconductor structure. In accordance with some embodiments, the semiconductor structure includes a substrate, one or more fins each including a first semiconductor layer formed over the substrate, an oxide layer formed wrapping over an upper portion of each of the one or more fins, and a gate stack including a high-K (HK) dielectric layer and a metal gate (MG) electrode formed wrapping over the oxide layer. The first semiconductor layer may include silicon germanium (SiGex), and the oxide layer may include silicon germanium oxide (SiGexOy).

Abstract: An RRAM array is provided. The RRAM array includes a plurality of horizontal electrode lines elongated in a horizontal direction. The RRAM array also includes a plurality of conducting structures elongated in a vertical direction. Each of the conducting structures includes a plurality of electrode blocks and a plurality of contact vias which are alternately arranged. The electrode blocks and the electrode lines are on the same horizontal planes. The RRAM array further includes a plurality of resistance variable elements sandwiched between the electrode lines and the electrode blocks.

Abstract: A semiconductor device is provided. The semiconductor device includes a channel region disposed between a source region and a drain region, a gate structure over the channel region, an interlayer dielectric (ILD) layer proximate the gate structure, an ILD stress layer proximate the top portion of gate structure and over the ILD layer. The gate structure includes a first sidewall, a second sidewall and a top portion. A first stress memorization region is also provided. The first stress memorization region is proximate the top portion of the gate structure. A method of making a semiconductor device is also provided.

Abstract: Embodiments of a semiconductor device structure and a method of fabricating the same are provided. The semiconductor device structure includes a substrate and a first layer formed over the substrate. The semiconductor device structure further includes a stress-reducing structure formed in the first layer, and a portion of the first layer is surrounded by the stress-reducing structure. The semiconductor device structure further includes a conductive feature formed in the portion of the first layer surrounded by the stress-reducing structure.

Abstract: Packaged semiconductor devices and methods of packaging semiconductor devices are disclosed. In some embodiments, a packaged semiconductor device includes an integrated circuit die, a molding compound disposed around the integrated circuit die, and an interconnect structure disposed over the integrated circuit die and the molding compound. The molding compound is thicker than the integrated circuit die.

Abstract: A device includes a patch antenna, which includes a feeding line, and a ground panel over the feeding line. The ground panel has an aperture therein. A low-k dielectric module is over and aligned to the aperture. A patch is over the low-k dielectric module.

Abstract: An embodiment is a device including a control circuit, a time-to-digital converter circuit coupled having a first output coupled to a first input of the control circuit, and a gating circuit having a first input coupled to a first signal, a second input coupled to a second signal, and an output coupled to a first input of the time-to-digital converter circuit, an output of the control circuit coupled to a second input of the time-to-digital converter circuit and to a third input of the gating circuit.

Abstract: Any defects in the reflective multilayer coating or absorber layer of an EUV mask are problematic in transferring a pattern of the EUV mask to a wafer since they produce errors in integrated circuit patterns on the wafer. In this regard, a method of manufacturing an EUV mask is provided according to various embodiments of the present disclosure. To repair the defect, a columnar reflector, which acts as a Bragg reflector, is deposited according to various embodiments so as to locally compensate and repair the defect. According to the embodiments of the present disclosure, the reflective loss due to the defect can be compensated and recover the phase different due to the defect from, so as to form a desirable wafer printed image.

Abstract: An integrated circuit includes a semiconductor substrate, a gate dielectric over the substrate, a metal gate structure over the semiconductor substrate and the gate dielectric, a dielectric film on the metal gate structure, the dielectric film comprising oxynitride combined with metal from the metal gate, and an interlayer dielectric (ILD) on either side of the metal gate structure.

Abstract: The embodiments of mechanisms for monitoring thermal budget of an etch process of a cyclic deposition/etch (CDE) process to form an epitaxially grown silicon-containing material are descried to enable and to improve process control of the material formation. The monitoring is achieved by measuring the temperature of each processed wafer as a function of process time to calculate the accumulated thermal budget (ATB) of the wafer and to compare the ATB with a reference ATB (or optimal accumulated thermal budget, OATB) to see if the processed wafer is within an acceptable range (or tolerance). The results are used to determine whether to pass the processed wafer or to reject the processed wafer.

Abstract: A system and method for forming and using a liner is provided. An embodiment comprises forming an opening in an inter-layer dielectric over a substrate and forming the liner along the sidewalls of the opening. A portion of the liner is removed from a bottom of the opening, and a cleaning process may be performed through the liner. By using the liner, damage to the sidewalls of the opening from the cleaning process may be reduced or eliminated. Additionally, the liner may be used to help implantation of ions within the substrate.

Abstract: An etching method comprises etching an oxide layer with a first dc bias of a plasma chamber, removing a photoresist layer with a second dc bias of the plasma chamber and etching through a liner film with a third dc bias of the plasma chamber. In order to reduce the copper deposition on the wall of the plasma chamber, the third dc bias is set to be less than the first and second dc bias.

Abstract: Methods for patterning fins for fin-like field-effect transistor (FinFET) devices are disclosed. An exemplary method includes providing a semiconductor substrate, forming a plurality of elongated protrusions on the semiconductor substrate, the elongated protrusions extending in a first direction, and forming a mask covering a first portion of the elongated protrusions, the mask being formed of a first material having a first etch rate. The method also includes forming a spacer surrounding the mask, the spacer being formed of a second material with an etch rate lower than the etch rate of the first material, the mask and the spacer together covering a second portion of the elongated protrusions larger than the first portion of the elongated protrusions. Further, the method includes removing a remaining portion of the plurality of elongated protrusions not covered by the mask and spacer.

Abstract: A Static Random Access Memory (SRAM) cell includes a first and a second pull-up transistor, a first and a second pull-down transistor forming cross-latched inverters with the first and the second pull-up transistors, and a first and a second pass-gate transistor. Each of the first and the second pull-up transistors, the first and the second pull-down transistors, and the first and the second pass-gate transistors includes a bottom plate as a first source/drain region, a channel over the bottom plate, and a top plate as a second source/drain region. A first isolated active region is in the SRAM cell and acts as the bottom plate of the first pull-down transistor and the bottom plate of the first pass-gate transistor. A second isolated active region is in the SRAM cell and acts as the bottom plate of the second pull-down transistor and the bottom plate of the second pass-gate transistor.

Abstract: A method performed using a resistive device, where the resistive device includes a substrate with an active region separated from a gate electrode by a dielectric and electrical contacts along a longest dimension of the gate electrode, the method comprising, performing one or more processes to form the resistive device, measuring a resistance between the electrical contacts, and correlating the measured resistance with a variation in one or more of the processes.