Abstract: A method for manufacturing a semiconductor device includes: providing a wafer-bonding stack structure having a sidewall layer and an exposed first component layer; forming a photoresist layer on the first component layer; performing an edge trimming process to at least remove the sidewall layer; and removing the photoresist layer. In this way, contaminant particles generated from the blade during the edge trimming process may fall on the photoresist layer but not fall on the first component layer, so as to protect the first component layer from being contaminated.

Abstract: A complementary high electron mobility transistor includes an N-type HEMT and an P-type HEMT disposed on the substrate. The N-type HEMT includes a first undoped gallium nitride layer, a first quantum confinement channel, a first undoped group III-V nitride compound layer and an N-type group III-V nitride compound layer disposed from bottom to top. A first gate is disposed on the N-type group III-V nitride compound layer. A first source and a first drain are disposed at two sides of the first gate. The P-type HEMT includes a second undoped gallium nitride layer, a second quantum confinement channel, a second undoped group III-V nitride compound layer and a P-type group III-V nitride compound layer disposed from bottom to top. A second gate is disposed on the P-type group III-V nitride compound layer. A second source and a second drain are disposed at two sides of the second gate.

Abstract: An insulated gate bipolar transistor includes a P-type group III-V nitride compound layer. An N-type group III-V nitride compound layer contacts a side of the P-type group III-V nitride compound layer. An HEMT is disposed on the N-type group III-V nitride compound layer. The HEMT includes a first group III-V nitride compound layer disposed on the N-type group III-V nitride compound layer. A second group III-V nitride compound layer is disposed on the first group III-V nitride compound layer. A source is embedded within the second group III-V nitride compound layer and the first group III-V nitride compound layer, wherein the source includes an N-type group III-V nitride compound body and a metal contact. A drain contacts another side of the P-type group III-V nitride compound layer. A gate is disposed on the second group III-V nitride compound layer.

Abstract: A method and an apparatus for semiconductor manufacturing process prediction based on heterogeneous data are provided. The method includes the following steps. Several equipment recipe data of several pieces of equipment are obtained. The equipment recipe data are inputted into a first Neural Network model to obtain a first prediction result. Several equipment sensing data are obtained. The equipment sensing data are inputted into a second Neural Network model to obtain a second prediction result. Several metrology inspection data are obtained. The equipment recipe data, the equipment sensing data and the metrology inspection data are heterogeneous data. The metrology inspection data are inputted into a third Neural Network model to obtain a third prediction result. According to the first prediction result, the second prediction result and the third prediction result, a total prediction result is obtained.

Abstract: A semiconductor process prediction method and a semiconductor process prediction apparatus considering overall features and local features are provided. The semiconductor manufacturing process prediction method includes the following steps. Several equipment sensing curves are obtained. The equipment sensing curves are filtered to reduce the co-linearity of the equipment sensing curves. A Dynamic Time Warping (DTW) procedure is performed to align the equipment sensing curves. The equipment sensing curves which are aligned are inputted into a Convolutional Neural Network (CNN) model to obtain a first prediction result considering the local features. A statistical analysis procedure is performed on the equipment sensing curves to obtain several statistical data. The statistical data are inputted into an Artificial Neural Network (ANN) model to obtain a second prediction result considering the overall features.

Abstract: For improving wafer fabrication, yield and lifetime of wafers are predicted by determining coefficients of a yield domain for wafer yield prediction and a lifetime domain for a wafer lifetime prediction, an integral domain, an electric/layout domain, a metrology/defect domain, and a machine sensor domain in a hierarchical manner. With the aid of the hierarchically-determined coefficients, noises in prediction can be reduced so that precision of prediction results of the yields or the lifetimes of wafers can be raised.

Abstract: A semiconductor device including a substrate, a plurality of isolation structures, at least a gate structure, a plurality of dummy gate structures and a plurality of epitaxial structures is provided. The substrate has an active area defined by the isolation structures disposed within the substrate. That is, the active area is defined between the isolation structures. The gate structure is disposed on the substrate and located within the active area. The dummy gate structures are disposed on the substrate and located out of the active area. The edge of each dummy gate structure is separated from the boundary of the active area with a distance smaller than 135 angstroms. The epitaxial structures are disposed within the active area and in a portion of the substrate on two sides of the gate structure. The invention also provided a method for fabricating semiconductor device.

Abstract: A stacked semiconductor structure and a manufacturing method for the same are provided. The stacked semiconductor structure is provided, which comprises a first semiconductor substrate, a second semiconductor substrate, a dielectric layer, a trench, a via, and a conductive structure. The first semiconductor substrate comprises a first substrate portion and a first conductive layer on an active surface of the first substrate portion. The second semiconductor substrate comprises a second substrate portion and a second conductive layer on an active surface of the second substrate portion. The trench passes through the second substrate portion and exposing the second conductive layer. The via passes through the dielectric layer and exposes the first conductive layer. The conductive structure has an upper portion filling the trench and a lower portion filling the via. Opposing side surfaces of the upper portion are beyond opposing side surfaces of the lower portion.

Abstract: A semiconductor device including a substrate, a plurality of isolation structures, at least a gate structure, a plurality of dummy gate structures and a plurality of epitaxial structures is provided. The substrate has an active area defined by the isolation structures disposed within the substrate. That is, the active area is defined between the isolation structures. The gate structure is disposed on the substrate and located within the active area. The dummy gate structures are disposed on the substrate and located out of the active area. The edge of each dummy gate structure is separated from the boundary of the active area with a distance smaller than 135 angstroms. The epitaxial structures are disposed within the active area and in a portion of the substrate on two sides of the gate structure. The invention also provided a method for fabricating semiconductor device.

Abstract: A semiconductor device including a substrate, a plurality of isolation structures, at least a gate structure, a plurality of dummy gate structures and a plurality of epitaxial structures is provided. The substrate has an active area defined by the isolation structures disposed within the substrate. That is, the active area is defined between the isolation structures. The gate structure is disposed on the substrate and located within the active area. The dummy gate structures are disposed on the substrate and located out of the active area. The edge of each dummy gate structure is separated from the boundary of the active area with a distance smaller than 135 angstroms. The epitaxial structures are disposed within the active area and in a portion of the substrate on two sides of the gate structure. The invention also provided a method for fabricating semiconductor device.

Abstract: For improving wafer fabrication, yield and lifetime of wafers are predicted by determining coefficients of a yield domain for wafer yield prediction and a lifetime domain for a wafer lifetime prediction, an integral domain, an electric/layout domain, a metrology/defect domain, and a machine sensor domain in a hierarchical manner. With the aid of the hierarchically-determined coefficients, noises in prediction can be reduced so that precision of prediction results of the yields or the lifetimes of wafers can be raised.

Abstract: A multi-gate transistor device includes a substrate, a fin structure extending along a first direction formed on the substrate, a gate structure extending along a second direction formed on the substrate, a drain region having a first conductivity type formed in the fin structure, a source region having a second conductivity type formed in the fin structure, and a first pocket doped region having the first conductivity type formed in and encompassed by the source region. The first conductivity type and the second conductivity type are complementary to each other.

Abstract: For improving wafer fabrication, yield and lifetime of wafers are predicted by determining coefficients of a yield domain for wafer yield prediction and a lifetime domain for a wafer lifetime prediction, an integral domain, an electric/layout domain, a metrology/defect domain, and a machine sensor domain in a hierarchical manner. With the aid of the hierarchically-determined coefficients, noises in prediction can be reduced so that precision of prediction results of the yields or the lifetimes of wafers can be raised.

Abstract: A stacked semiconductor structure and a manufacturing method for the same are provided. The stacked semiconductor structure is provided, which comprises a first semiconductor substrate, a second semiconductor substrate, a dielectric layer, a trench, a via, and a conductive structure. The first semiconductor substrate comprises a first substrate portion and a first conductive layer on an active surface of the first substrate portion. The second semiconductor substrate comprises a second substrate portion and a second conductive layer on an active surface of the second substrate portion. The trench passes through the second substrate portion and exposing the second conductive layer. The via passes through the dielectric layer and exposes the first conductive layer. The conductive structure has an upper portion filling the trench and a lower portion filling the via. Opposing side surfaces of the upper portion are beyond opposing side surfaces of the lower portion.

Abstract: A wafer fabrication outcome, such as wafer yield or wafer lifetime, is predicted by excluding uncontrollable but measurable internal/external noises of a DOE system, and by rendering relations between wafer design variables and wafer outcome outputs to be more causal, as well as the relations between variances for each of the wafer design variables and the wafer outcome outputs. With the aid of a wafer fabrication outcome predicting model formed by the more causal relations, precision of predicting wafer outcomes can be raised, and performance of wafer fabrication can be thus raised as a result.

Abstract: A layout correcting method and a layout correcting system are provided. The layout correcting method includes the following steps. An integrated circuit design layout is provided. A plurality of performance parameters of the integrated circuit design layout are analyzed. A plurality of devices under test is selected according to the performance parameters. A computer simulating process is performed on the devices under test and a direct probing process is performed on the devices under test. The direct probing process is an on-chip test for comparing each device under test and an environment condition thereof by a Boolean algebra algorithm. A plurality of differences between the results of the computer simulating process and the direct probing process is analyzed. The integrated circuit design layout is corrected according to differences between the results of the computer simulating process and the direct probing process.

Abstract: For improving wafer fabrication, yield and lifetime of wafers are predicted by determining coefficients of a yield domain for wafer yield prediction and a lifetime domain for a wafer lifetime prediction, an integral domain, an electric/layout domain, a metrology/defect domain, and a machine sensor domain in a hierarchical manner. With the aid of the hierarchically-determined coefficients, noises in prediction can be reduced so that precision of prediction results of the yields or the lifetimes of wafers can be raised.

Abstract: A transistor array for testing is provided. The transistor array includes a plurality of tested units. Each of the tested unit includes a tested transistor and a first to third switches. The tested transistor has a control terminal, a first and a second terminals and a bulk. The first switch is coupled between the first terminal and a leakage transporting line. The second switch is coupled between the second terminal and the leakage transporting line. The third switch is coupled between the control terminal and a bias providing line. The first to third switches are turned on or turned off according to a control signal. When the tested transistor is selected to be tested, the first to third switches are turned on according to the control signal.

Abstract: A semiconductor device including a substrate, a plurality of isolation structures, at least a gate structure, a plurality of dummy gate structures and a plurality of epitaxial structures is provided. The substrate has an active area defined by the isolation structures disposed within the substrate. That is, the active area is defined between the isolation structures. The gate structure is disposed on the substrate and located within the active area. The dummy gate structures are disposed on the substrate and located out of the active area. The edge of each dummy gate structure is separated from the boundary of the active area with a distance smaller than 135 angstroms. The epitaxial structures are disposed within the active area and in a portion of the substrate on two sides of the gate structure. The invention also provided a method for fabricating semiconductor device.

Abstract: A multi-gate transistor device includes a substrate, a fin structure extending along a first direction formed on the substrate, a gate structure extending along a second direction formed on the substrate, a drain region having a first conductivity type formed in the fin structure, a source region having a second conductivity type formed in the fin structure, and a first pocket doped region having the first conductivity type formed in and encompassed by the source region. The first conductivity type and the second conductivity type are complementary to each other.