Abstract: A flyback power converter includes a power transformer, a first lossless voltage conversion circuit, a first low-dropout linear regulator and a secondary side power supply circuit. The first low-dropout linear regulator (LDO) generates a first operation voltage as power supply for being supplied to a sub-operation circuit. The secondary side power supply circuit includes a second lossless voltage conversion circuit and a second LDO. The second LDO generates a second operation voltage. The first operation voltage and the second operation voltage are shunted to a common node. When a first lossless conversion voltage is greater than a first threshold voltage, the second LDO is enabled to generate the second operation voltage to replace the first operation voltage as power supply supplied to the sub-operation circuit; wherein the second lossless conversion voltage is lower than the first lossless switching voltage.

Abstract: A magnetic tunnel junction (MTJ) structure of a magnetic random access memory (MRAM) cell includes an insulation layer, a patterned MTJ film stack, an aluminum oxide protection layer, an interlayer dielectric, and a connection structure. The patterned MTJ film stack is disposed on the insulation layer. The aluminum oxide protection layer is disposed on a sidewall of the patterned MTJ film stack, and the aluminum oxide protection layer includes an aluminum film oxidized by an oxidation treatment. The interlayer dielectric covers the aluminum oxide protection layer and the patterned MTJ film stack. The connection structure penetrates the interlayer dielectric above the patterned MTJ film stack, and the connection structure is electrically connected to a topmost portion of the patterned MTJ film stack.

Abstract: A magnetic tunnel junction (MTJ) structure of a magnetic random access memory (MRAM) cell includes an insulation layer, a patterned MTJ film stack, an aluminum oxide protection layer, an interlayer dielectric, and a connection structure. The patterned MTJ film stack is disposed on the insulation layer. The aluminum oxide protection layer is disposed on a sidewall of the patterned MTJ film stack, and the aluminum oxide protection layer includes an aluminum film oxidized by an oxidation treatment. The interlayer dielectric covers the aluminum oxide protection layer and the patterned MTJ film stack. The connection structure penetrates the interlayer dielectric above the patterned MTJ film stack, and the connection structure is electrically connected to a topmost portion of the patterned MTJ film stack.

Abstract: A manufacturing method of a magnetic random access memory (MRAM) cell includes the following steps. A magnetic tunnel junction (MTJ) film stack is formed on an insulation layer. An aluminum mask layer is formed on the MTJ film stack. A hard mask layer is formed on the aluminum mask layer. An ion beam etching (IBE) process is performed with the aluminum mask layer and the hard mask layer as a mask. The MTJ film stack is patterned to be a patterned MTJ film stack by the IBE process, and at least apart of the aluminum mask layer is bombarded by the IBE process for forming an aluminum film on a sidewall of the patterned MTJ film stack. An oxidation treatment is performed, and the aluminum film is oxidized to be an aluminum oxide protection layer on the sidewall of the patterned MTJ film stack by the oxidation treatment.

Abstract: A manufacturing method of a magnetic random access memory (MRAM) cell includes the following steps. A magnetic tunnel junction (MTJ) film stack is formed on an insulation layer. An aluminum mask layer is formed on the MTJ film stack. A hard mask layer is formed on the aluminum mask layer. An ion beam etching (IBE) process is performed with the aluminum mask layer and the hard mask layer as a mask. The MTJ film stack is patterned to be a patterned MTJ film stack by the IBE process, and at least apart of the aluminum mask layer is bombarded by the IBE process for forming an aluminum film on a sidewall of the patterned MTJ film stack. An oxidation treatment is performed, and the aluminum film is oxidized to be an aluminum oxide protection layer on the sidewall of the patterned MTJ film stack by the oxidation treatment.

Abstract: The present invention provides a semiconductor structure, the semiconductor structure includes a substrate comprising a diffusion region, a transistor structure on the substrate, and a resistive random access memory (RRAM) on the substrate, wherein the resistive random access memory includes at least one metal silicide layer in direct contact with the diffusion region, and a lower electrode, a resistive switching layer and an upper electrode are sequentially disposed on the metal silicide layer.

Abstract: The present invention provides a semiconductor structure, the semiconductor structure includes a fin transistor (fin filed effect transistor, finFET) located on a substrate, the fin transistor includes a gate structure crossing over a fin structure, and at least one source/drain region. And a resistive random access memory (RRAM) includes a lower electrode, a resistance switching layer and a top electrode being sequentially located on the source/drain region and electrically connected to the fin transistor.

Abstract: The present invention provides a semiconductor structure, the semiconductor structure includes a fin transistor (fin filed effect transistor, finFET) located on a substrate, the fin transistor includes a gate structure crossing over a fin structure, and at least one source/drain region. And a resistive random access memory (RRAM) includes a lower electrode, a resistance switching layer and a top electrode being sequentially located on the source/drain region and electrically connected to the fin transistor.

Abstract: The present invention provides a semiconductor structure, the semiconductor structure includes a substrate comprising a diffusion region, a transistor structure on the substrate, and a resistive random access memory (RRAM) on the substrate, wherein the resistive random access memory includes at least one metal silicide layer in direct contact with the diffusion region, and a lower electrode, a resistive switching layer and an upper electrode are sequentially disposed on the metal silicide layer.

Abstract: A resistive random access memory (RRAM) cell includes a substrate, a transistor having a gate on the substrate and a source/drain region in the substrate, a first inter-layer dielectric layer covering the transistor, a contact plug disposed in the first inter-layer dielectric layer and landing on the source/drain region, a resistive material layer conformally covering a protruding upper end portion of the contact plug, and a top electrode on the resistive material layer.

Abstract: A method for fabricating a silicon nitride gap-filling layer is provided. A pre-multi-step formation process is performed to form a stacked layer constituting as a dense film on a substrate. Then, a post-single step deposition process is conducted to form a cap layer constituting as a sparse film on the stacked layer, wherein the cap layer has a thickness of at least 10% of the total film thickness.

Abstract: A method for forming a plug structure includes the following steps. A substrate is provided. The substrate includes a MOS device with a source/drain region, a dielectric layer disposed on the MOS device, an opening defined in the dielectric layer, and a first glue layer disposed on a sidewall and a bottom of the opening. A portion of the first glue layer disposed at the bottom of the opening is punched through to expose the source/drain region. A barrier layer is formed over the substrate after the first glue layer is punched through. The opening is filled with a conductive structure, wherein the barrier layer disposed at the bottom of the opening is remained when the conductive structure is filled into the opening.

Abstract: A semiconductor device including a substrate, a gate structure, a spacer and source/drain regions is provided. The gate structure is on the substrate, wherein the gate structure includes, from bottom to top, a high-k layer, a work function metal layer, a wetting layer and a metal layer. The spacer is on a sidewall of the gate structure. The source/drain regions are in the substrate beside the gate structure.

Abstract: During a salicide process, and before a second thermal treatment is performed to a silicide layer of a semiconductor substrate, a thermal conductive layer is formed to cover the silicide layer. The heat provided by the second thermal treatment can be conducted to the silicide layer uniformly through the thermal conductive layer. The thermal conductive layer can be a CESL layer, TiN, or amorphous carbon. Based on different process requirements, the thermal conductive layer can be removed optionally after the second thermal treatment is finished.

Abstract: A semiconductor device including a substrate, a gate structure, a spacer and source/drain regions is provided. The gate structure is on the substrate, wherein the gate structure includes, from bottom to top, a high-k layer, a work function metal layer, a wetting layer and a metal layer. The spacer is on a sidewall of the gate structure. The source/drain regions are in the substrate beside the gate structure.

Abstract: A method of fabricating a strained silicon transistor is provided. Amorphous silicon is formed below the transistor region before the transistor is formed. By using the tensile/compressive strainer, amorphous silicon is recrystallized to form a strained silicon layer. In addition, the dopants in the well can be driven in and activated by using the same annealing process with the amorphous silicon recrystallization.

Abstract: A method for forming a plug structure includes the following steps. A substrate is provided. The substrate includes a MOS device with a source/drain region, a dielectric layer disposed on the MOS device, an opening defined in the dielectric layer, and a first glue layer disposed on a sidewall and a bottom of the opening. A portion of the first glue layer disposed at the bottom of the opening is punched through to expose the source/drain region. A barrier layer is formed over the substrate after the first glue layer is punched through. The opening is filled with a conductive structure, wherein the barrier layer disposed at the bottom of the opening is remained when the conductive structure is filled into the opening.

Abstract: A method of forming a semiconductor device is described. First, a substrate is provided. Thereafter, a gate structure including, from bottom to top, a high-k layer, a work function metal layer, a wetting layer, a polysilicon layer and a mask layer is formed on the substrate. Afterwards, a spacer is formed on the sidewall of the gate structure. Source/drain regions are then formed in the substrate beside the gate structure. Further, an interlayer dielectric layer is formed over the substrate. Thereafter, a portion of the interlayer dielectric layer is removed to expose the surface of the mask layer. Afterwards, the mask layer and the polysilicon layer are sequentially removed to expose the surface of the wetting layer. A selective chemical vapor deposition process is then performed, so as to bottom-up deposit a metal layer from the surface of the wetting layer.

Abstract: A semiconductor process is provided. The semiconductor process includes providing a substrate. Then, a surface treatment is performed to the substrate to form a buffer layer on the substrate. Next, a first pre-amorphous implantation is performed to the substrate.

Abstract: A method of removing material layer is disclosed. First, a semiconductor substrate is fixed on a rotating platform, where a remnant material layer is included on the surface of the semiconductor substrate. Afterward, an etching process is carried out. In the etching process, the rotating platform is rotated, and an etching solution is sprayed from a center region and a side region of the rotating platform toward the semiconductor substrate until the material layer is removed. Since the semiconductor substrate is etched by the etching solution sprayed from both the center region and the side region of the rotating platform, the etching uniformity of the semiconductor substrate is improved.