Abstract: An apparatus for wafer bonding includes a transfer module and a plasma module. The transfer module is configured to transfer a semiconductor wafer. The plasma module is configured to apply a first type of plasma to perform a reduction operation upon a surface of the semiconductor wafer at a temperature within a predetermined temperature range to convert metal oxides on the surface of the semiconductor wafer to metal, and apply a second type of plasma to perform a plasma operation upon the surface of the semiconductor wafer at a room temperature outside the predetermined temperature range to activate a surface of the semiconductor wafer.

Abstract: Various embodiments of the present disclosure are directed towards a memory cell. The memory cell includes a bottom electrode overlying a substrate. A data storage structure overlies the bottom electrode. A top electrode overlies the data storage structure. Sidewalls of the top electrode and sidewall of the bottom electrode are aligned. Further, a getter layer abuts the bottom electrode.

Abstract: In a method of manufacturing a semiconductor device, a first interlayer dielectric (ILD) layer is formed over a substrate, a chemical mechanical polishing (CMP) stop layer is formed over the first ILD layer, a trench is formed by patterning the CMP stop layer and the first ILD layer, a metal layer is formed over the CMP stop layer and in the trench, a sacrificial layer is formed over the metal layer, a CMP operation is performed on the sacrificial layer and the metal layer to remove a portion of the metal layer over the CMP stop layer, and a remaining portion of the sacrificial layer over the trench is removed.

Abstract: An apparatus and a method for wafer bonding are provided. The apparatus comprises a transfer module and a plasma module. The transfer module is configured to transfer a semiconductor wafer. The plasma module is configured to perform a plasma operation and a reduction operation to a surface of the semiconductor wafer to convert metal oxides on the surface of the semiconductor wafer to the metal.

Abstract: A phase change memory (PCM) device including a PCM structure with a getter metal layer disposed between a phase change element (PCE) and a dielectric layer is provided. The PCM structure includes a dielectric layer, a bottom electrode, a via, a PCE, and a getter metal layer. The dielectric layer is disposed over a substrate. The bottom electrode overlies the dielectric layer. The via extends through the dielectric layer, from a bottom surface of the dielectric layer to a top surface of the dielectric layer. The phase change element overlies the bottom electrode. The getter metal layer is disposed between the dielectric layer and the PCE.

Abstract: A method for manufacturing a semiconductor device includes forming a structure protruding from a substrate, forming a dielectric layer covering the structure, forming a dummy layer covering the dielectric layer, and performing a planarization process to completely remove the dummy layer. A material of the dummy layer has a slower removal rate to the planarization process than a material of the dielectric layer.

Abstract: A phase change memory (PCM) device including a PCM structure with a getter metal layer disposed between a phase change element (PCE) and a dielectric layer is provided. The PCM structure includes a dielectric layer, a bottom electrode, a via, a PCE, and a getter metal layer. The dielectric layer is disposed over a substrate. The bottom electrode overlies the dielectric layer. The via extends through the dielectric layer, from a bottom surface of the dielectric layer to a top surface of the dielectric layer. The phase change element overlies the bottom electrode. The getter metal layer is disposed between the dielectric layer and the PCE.

Abstract: A method for manufacturing a semiconductor device includes forming a structure protruding from a substrate, forming a dielectric layer covering the structure, forming a dummy layer covering the dielectric layer, and performing a planarization process to completely remove the dummy layer. A material of the dummy layer has a slower removal rate to the planarization process than a material of the dielectric layer.

Abstract: The present disclosure relates to a chemical mechanical polishing (CMP) pad, and an associated method to perform a CMP process. In some embodiments, the CMP pad comprises a polishing layer having a front surface with protruding asperities while a back surface being planar. A film electrode is attached to the back surface of the polishing layer and is isolated from the front surface of the polishing layer.

Abstract: The present disclosure relates to a chemical mechanical polishing (CMP) system, and an associated method to perform a CMP process. In some embodiments, the CMP system has a rotatable wafer carrier configured to hold a wafer face down to be processed. The CMP system also has a polishing layer attached to a polishing platen and having a front surface configured to interact with the wafer to be processed, and a CMP dispenser configured to dispense a slurry between an interface of the polishing layer and the wafer. The slurry contains charged abrasive particles therein. The CMP system also has a film electrode attached to a back surface of the polishing layer opposite to the front surface. The film electrode is configured to affect movements of the charged abrasive particles through applying an electrical field during the operation of the CMP system.

Abstract: A method for estimating film thickness in CMP includes the following operations. A substrate with a film formed thereon is disposed over a polishing pad with a slurry dispensed between the film and the polishing pad. A CMP operation is performed to reduce a thickness of the film. An in-situ electrochemical impedance spectroscopy (EIS) measurement is performed during the CMP operation by an EIS device to estimate the thickness of the film real-time. The CMP operation is ended when the estimated thickness of the film obtained from the fit parameters of the first equivalent electrical circuit model reaches a target thickness.

Abstract: A method for manufacturing a semiconductor device includes forming a structure protruding from a substrate, forming a dielectric layer covering the structure, forming a dummy layer covering the dielectric layer, and performing a planarization process to completely remove the dummy layer. A material of the dummy layer has a slower removal rate to the planarization process than a material of the dielectric layer.

Abstract: An integrated circuit or semiconductor structure of a resistive random access memory (RRAM) cell is provided. The RRAM cell includes a bottom electrode and a data storage region having a variable resistance arranged over the bottom electrode. Further, the RRAM cell includes a diffusion barrier layer arranged over the data storage region, an ion reservoir region arranged over the diffusion barrier layer, and a top electrode arranged over the ion reservoir region. A method for manufacture the integrated circuit or semiconductor structure of the RRAM cell is also provided.

Abstract: The present disclosure relates to a chemical mechanical polishing (CMP) system, and an associated method to perform a CMP process. In some embodiments, the CMP system has a rotatable wafer carrier configured to hold a wafer face down to be processed. The CMP system also has a polishing layer attached to a polishing platen and having a front surface configured to interact with the wafer to be processed, and a CMP dispenser configured to dispense a slurry between an interface of the polishing layer and the wafer. The slurry contains charged abrasive particles therein. The CMP system also has a film electrode attached to a back surface of the polishing layer opposite to the front surface. The film electrode is configured to affect movements of the charged abrasive particles through applying an electrical field during the operation of the CMP system.

Abstract: A getter is provided. The getter consists essentially of from about 0% to 50% of titanium, from about 0% to 50% zirconium, and from about 5% to 50% of tantalum. A MEMS device is provided. The MEMS device includes a substrate and a getter over the substrate. The getter consists essentially of from about 0% to 50% of titanium, from about 0% to 50% zirconium, and from about 5% to 50% of tantalum. A method of forming a MEMS device is provided. The method includes the following operations: providing a substrate; and providing a getter over the substrate, wherein the getter consists essentially of from about 0% to 50% of titanium, from about 0% to 50% zirconium, and from about 5% to 50% of tantalum, and wherein all of the percentages are atomic percentages.

Abstract: A semiconductor device includes a first bottom electrode, a second bottom electrode, a switching layer and a top electrode. The first bottom electrode has two edges opposite to each other, and an upper surface. The second bottom electrode is between the edges of the first bottom electrode and exposed from the upper surface of the first bottom electrode. The switching layer is over the first bottom electrode and the second bottom electrode. The top electrode is over the switching layer.

Abstract: Embodiments of forming an image sensor with organic photodiodes are provided. Trenches are formed in the organic photodiodes to increase the PN junction interfacial area, which improves the quantum efficiency (QE) of the photodiodes. The organic P-type material is applied in liquid form to fill the trenches. A mixture of P-type materials with different work function values and thickness can be used to meet the desired work function value for the photodiodes.

Abstract: A semiconductor device includes a first bottom electrode, a second bottom electrode, a switching layer and a top electrode. The first bottom electrode has two edges opposite to each other, and an upper surface. The second bottom electrode is between the edges of the first bottom electrode and exposed from the upper surface of the first bottom electrode. The switching layer is over the first bottom electrode and the second bottom electrode. The top electrode is over the switching layer.

Abstract: Embodiments of forming an image sensor with organic photodiodes are provided. Trenches are formed in the organic photodiodes to increase the PN-junction interfacial area, which improves the quantum efficiency (QE) of the photodiodes. The organic P-type material is applied in liquid form to fill the trenches. A mixture of P-type materials with different work function values and thickness can be used to meet the desired work function value for the photodiodes.

Abstract: Embodiments of forming an image sensor with an organic photodiode are provided. The organic photodiode uses dual electron-blocking layers formed next to the anode of the organic photodiode to reduce dark current. By using dual electron-blocking layers, the values of highest occupied molecular orbital (HOMO) for the neighboring anode layer and the organic electron-blocking layer are matched by one of the dual electron-blocking layers to form a photodiode with good performance. The values of the lowest occupied molecular orbital (LOMOs) of the dual electron-blocking layers are selected to be lower than the neighboring anode layer to reduce dark current.