Abstract: The present disclosure relates to a chimeric influenza virus hemagglutinin (HA) polypeptide, comprising one or more stem domain sequence, each having at least 60% homology with a stem domain consensus sequence of H1 subtype HA (H1 HA) and/or H5 subtype HA (H5 HA), fused with one or more globular head domain sequence, each having at least 60% homology with a globular head domain consensus sequence of H1 subtype HA (H1 HA) or H5 subtype HA (H5 HA).

Abstract: An optical system affixed to an electronic apparatus is provided, including a first optical module, a second optical module, and a third optical module. The first optical module is configured to adjust the moving direction of a first light from a first moving direction to a second moving direction, wherein the first moving direction is not parallel to the second moving direction. The second optical module is configured to receive the first light moving in the second moving direction. The first light reaches the third optical module via the first optical module and the second optical module in sequence. The third optical module includes a first photoelectric converter configured to transform the first light into a first image signal.

Abstract: The present disclosure relates to a chimeric influenza virus hemagglutinin (HA) polypeptide, comprising one or more stem domain sequence, each having at least 60% homology with a stem domain consensus sequence of H1 subtype HA (H1 HA) and/or H5 subtype HA (H5 HA), fused with one or more globular head domain sequence, each having at least 60% homology with a globular head domain consensus sequence of H1 subtype HA (H1 HA) or H5 subtype HA (H5 HA).

Abstract: A method for predicting an attacked path on enterprise networks includes: obtaining a plurality of accounts, a plurality of machines and network resource data, where the plurality of machines include at least one attacked target; calculating, according to the network resource data, a plurality of evaluated values of executing access on other machines of each account logging in at least one machine; and presenting an attacked path where a machine at least one account logs in accesses the attacked target directly, or indirectly by connecting to other machines, and the machine the at least one account logs in points to the attacked target directly, or indirectly by connecting to other machines.

Abstract: A device includes a fin structure, a gate structure, a first source/drain epitaxial structure and, a second source/drain epitaxial structure. The fin structure over a substrate and includes a bottom portion protruding from the substrate and a top portion over the bottom portion. An interface between the bottom portion and the top portion comprises oxygen and has an oxygen concentration lower than about 1.E+19 atoms/cm3. The gate structure covers the fin structure. The first source/drain epitaxial structure and the second source/drain epitaxial structure are over the top portion of the fin structure and on opposite sides of the gate structure.

Abstract: In an embodiment, a device includes a substrate, a first semiconductor layer that extends from the substrate, and a second semiconductor layer on the first semiconductor layer. The first semiconductor layer includes silicon and the second semiconductor layer includes silicon germanium, with edge portions of the second semiconductor layer having a first germanium concentration, a center portion of the second semiconductor layer having a second germanium concentration, and the second germanium concentration being less than the first germanium concentration. The device also includes a gate stack on the second semiconductor layer, lightly doped source/drain regions in the second semiconductor layer, and source and drain regions extending into the lightly doped source/drain regions.

Abstract: A method includes forming an implanted region in a substrate. The implanted region is adjacent to a top surface of the substrate. A clean treatment is performed on the top surface of the implanted region. The top surface of the implanted region is baked after the clean treatment. An epitaxial layer is formed on the top surface of the substrate. The epitaxial layer is patterned to form a fin.

Abstract: A method includes forming a fin protruding from a substrate; forming an isolation region surrounding the fin; forming a gate structure extending over the fin and the isolation region; etching the fin adjacent the gate structure to form a recess; forming a source/drain region in the recess, including performing a first epitaxial process to grow a first semiconductor material in the recess, wherein the first epitaxial process preferentially forms facet planes of a first crystalline orientation; and performing a second epitaxial process to grow a second semiconductor material on the first semiconductor material, wherein the second epitaxial process preferentially forms facet planes of a second crystalline orientation, wherein a top surface of the second semiconductor material is above a top surface of the fin; and forming a source/drain contact on the source/drain region.

Abstract: In an embodiment, a device includes a substrate, a first semiconductor layer that extends from the substrate, and a second semiconductor layer on the first semiconductor layer. The first semiconductor layer includes silicon and the second semiconductor layer includes silicon germanium, with edge portions of the second semiconductor layer having a first germanium concentration, a center portion of the second semiconductor layer having a second germanium concentration, and the second germanium concentration being less than the first germanium concentration. The device also includes a gate stack on the second semiconductor layer, lightly doped source/drain regions in the second semiconductor layer, and source and drain regions extending into the lightly doped source/drain regions.

Abstract: In an embodiment, a method of forming a semiconductor device includes forming a fin protruding above a substrate; forming a gate structure over the fin; forming a recess in the fin and adjacent to the gate structure; performing a wet etch process to clean the recess; treating the recess with a plasma process; and performing a dry etch process to clean the recess after the plasma process and the wet etch process.

Abstract: A method for smoothing a surface of a semiconductor portion is disclosed. In the method, an intentional oxide layer is formed on the surface of the semiconductor portion, a treated layer is formed in the semiconductor portion and inwardly of the intentional oxide layer, and then, the intentional oxide layer and the treated layer are removed to obtain a smoothed surface. The method may also be used for widening a recess in a manufacturing process for a semiconductor structure.

Abstract: The present invention provides an event visualization device configured to generate one or more directed acyclic graphs (DAGs) that can be used as a basis for diagnosing whether a target network system has been hacked according to a plurality of activities records. The plurality of activities records pertain to an event cluster associated with a suspicious event category. The event visualization device performs a graph generating operation on the plurality of activities records in a recursive manner to generate a hierarchical directed acyclic graph (HDAG). The graph generating operation includes: interpreting an activities record into a target DAG, and performing a hierarchical partial order alignment (HPOA) operation on the target DAG and a reference DAG to obtain a merging condition of each node; and merging the target DAG and the reference DAG into the HDAG according to the merging condition.

Abstract: The present invention provides a log classification system configured to perform a hierarchical similarity analysis operation according to a plurality of activities records to generate a discrete space metric tree, and perform a clustering operation on the discrete space metric tree to generate one or more event clusters associated with one or more suspicious event categories. The log classification system includes an output device configured to output the one or more event clusters to an information security incident diagnosis system, and allow the information security incident diagnosis system to calculate similar feature information and differential feature information of a plurality of activities records in the one or more event clusters as auxiliary information for diagnosing whether there are intrusions or abnormalities in a target network system.

Abstract: A method for removing nodule defects is disclosed. The nodule defects may be formed on a non-selected portion of a semiconductor structure during formation of a semiconductor region on a selected portion of the semiconductor structure. A plasma having a higher selectivity to etch the nodule defects relative to the semiconductor region may be used to selectively remove the nodule defects on the non-selected portion.

Abstract: The present invention provides an information security incident diagnosis system for assisting in detecting whether a target network system has been hacked. First, a plurality of activities records of one or more computing devices in a target network system are collected. Then, a discrete space metric tree is generated according to the plurality of activities records, and a clustering operation is performed on the discrete space metric tree to generate one or more event clusters associated with one or more suspicious event categories. Each event cluster may form a guide tree corresponding to the event cluster through single linkage clustering analysis to indicate a merging order from high to low similarity. The merging order is used for recursively performing a graph generating operation to convert a plurality of activities records corresponding to the one or more event clusters into a hierarchical directed acyclic graph (HDAG).

Abstract: In an embodiment, a method of forming a semiconductor device includes forming a fin protruding above a substrate; forming a gate structure over the fin; forming a recess in the fin and adjacent to the gate structure; performing a wet etch process to clean the recess; treating the recess with a plasma process; and performing a dry etch process to clean the recess after the plasma process and the wet etch process.

Abstract: A method includes forming a fin over a substrate, forming an isolation region adjacent the fin, forming a dummy gate structure over the fin, and recessing the fin adjacent the dummy gate structure to form a first recess using a first etching process. The method also includes performing a plasma clean process on the first recess, the plasma clean process including placing the substrate on a holder disposed in a process chamber, heating the holder to a process temperature between 300° C. and 1000° C., introducing hydrogen gas into a plasma generation chamber connected to the process chamber, igniting a plasma within the plasma generation chamber to form hydrogen radicals, and exposing surfaces of the recess to the hydrogen radicals. The method also includes epitaxially growing a source/drain region in the first recess.

Abstract: A method for smoothing a surface of a semiconductor portion is disclosed. In the method, an intentional oxide layer is formed on the surface of the semiconductor portion, a treated layer is formed in the semiconductor portion and inwardly of the intentional oxide layer, and then, the intentional oxide layer and the treated layer are removed to obtain a smoothed surface. The method may also be used for widening a recess in a manufacturing process for a semiconductor structure.

Abstract: A method for removing nodule defects is disclosed. The nodule defects may be formed on a non-selected portion of a semiconductor structure during formation of a semiconductor region on a selected portion of the semiconductor structure. A plasma having a higher selectivity to etch the nodule defects relative to the semiconductor region may be used to selectively remove the nodule defects on the non-selected portion.

Abstract: A method includes forming a fin over a substrate, forming an isolation region adjacent the fin, forming a dummy gate structure over the fin, and recessing the fin adjacent the dummy gate structure to form a first recess using a first etching process. The method also includes performing a plasma clean process on the first recess, the plasma clean process including placing the substrate on a holder disposed in a process chamber, heating the holder to a process temperature between 300° C. and 1000° C., introducing hydrogen gas into a plasma generation chamber connected to the process chamber, igniting a plasma within the plasma generation chamber to form hydrogen radicals, and exposing surfaces of the recess to the hydrogen radicals. The method also includes epitaxially growing a source/drain region in the first recess.