Abstract: A high-entropy transition metal layered oxide is an O3 type high-entropy transition metal layered oxide which is represented by the following formula (1): Na[NiaFebMncM1dM2e]O2??(1). In the formula (1), M1 and M2 are selected from a group consisting of V, Cr, Co, Cu, Zn, and Ti, a+b+c+d+e=1, 0.05?a?0.35, 0.05?b?0.35, 0.05?c?0.35, 0.05?d?0.35, and 0.05?e?0.35.

Abstract: A carbon nanomaterial for gas storage and a method for manufacturing the same are provided. The specific surface area of the carbon nanomaterial for gas storage is greater than 2000 m2/g. The mesopore volume of the carbon nanomaterial for gas storage is greater than the micropore volume of the carbon nanomaterial for gas storage, and the carbon nanomaterial for gas storage has a peak intensity ratio (ID/IG) between G band and D band, as determined from the Raman spectrum, between 1.1 and 2. In the carbon nanomaterial for gas storage, the pore volume of pores with a pore width of 6 nm or less is bigger than that of pores with a pore width greater than 6 nm.

Abstract: A semiconductor device includes a substrate, a bottom sublayer having a monoatomic layer thickness, disposed on the substrate, located at a bottom of the device, and extending in a horizontal direction, a metal sublayer having a monoatomic layer thickness, overlaying the bottom sublayer in the horizontal direction and electrically connected to the bottom sublayer, a top sublayer having a monoatomic layer thickness, disposed in the horizontal direction and electrically connected to the metal sublayer, and a contact metal layer disposed above the metal sublayer. A top surface of the contact metal layer is higher than a top surface of the top sublayer. Bottom layer contact metal atoms of the contact metal layer directly form corresponding bonds with a metal atom surface of the metal sublayer exposed after a portion of the top sublayer is stripped. Original corresponding bonds are maintained between the metal sublayer and the bottom sublayer.

Abstract: The art for the design of a class of modified catalysts, the process for preparing such modified catalysts and implementation of such modified catalysts in phosphoric acid fuel cells is disclosed. The modified catalyst comprises a particle of a metal-doped porous material and an amount of a phosphate-containing acid group or phosphate-containing acid groups. The particle of the metal-doped porous material is a particle of a porous carrier with metal microparticles and a plurality of hydroxyl groups on the surface of the porous carrier such that (i) the plurality of metal microparticles are attached to a first portion of the plurality of hydroxyl groups of the surface of the porous carrier and (ii) an amount of a phosphate-containing acid group or phosphate-containing acid groups can be bonded to a second portion of the plurality of hydroxyl groups of the surface of the porous carrier to form the modified catalyst.

Abstract: A 3D reconstruction method for a thin film sample that includes a light element is provided. The method includes performing preprocessing that includes noise removal, field-of-view correction and background subtraction on original projection images captured by a scanning transmission electron microscope to obtain 2D images, performing several rounds of a 3D reconstruction procedure that includes an alignment process and an iterative algorithm based on the 2D images and reference images to obtain a piece of reconstructed 3D image data, generating a reconstructed 3D image related to the thin film sample based on the piece of reconstructed 3D image data, and displaying the reconstructed 3D image.

Abstract: An image sensor chip and a sensing method thereof are disclosed. The image sensor chip includes pixel units. Each pixel unit includes a reset switch, a sampling switch, a light sensing element, a capacitor, and an output circuit. The sampling switch is coupled between the reset switch and the light sensing element. The capacitor is coupled between the sampling switch and the output circuit. The output circuit outputs difference information corresponding to a difference between a plurality of sensing results of the light sensing element in different frame periods to a corresponding readout line. The sampling switch has an ON-time length during an exposure period and an OFF-time length during a readout and clean-up period. A ratio of the ON-time length to the OFF-time length is related to a ratio of a capacitance of the light sensing element to a capacitance of the capacitor.

Abstract: A head-mounted device for reducing symptoms of cybersickness includes a main shell, and a stimulation unit. The main shell includes first, second and third tube bodies that are arc-shaped and that are worn respectively on the top and back of the user’s head and the user’s ear. The stimulation unit includes first, second and third components that are received respectively in the first, second and third tube bodies, that are movable in a rolling, sliding or flowing manner with low friction, and that are configured to generate and transmit a stimulation force, through one end of the respective one of the first, second and third tube bodies, to the use’s vestibular system in respond to movement of the user’s head.

Abstract: A laser processing system configured to provide a processing beam is provided. The laser processing system includes a laser, a beam splitting module, a first adjustment module, and a second adjustment module. The laser is configured to provide a laser beam. The beam splitting module is configured to split the laser beam into a first laser beam and a second laser beam. The first adjustment module is disposed on a transmission path of the first laser beam and configured to adjust the first laser beam to a central portion of the processing beam. The second adjustment module is disposed on a transmission path of the second laser beam and configured to adjust the second laser beam to an outer ring portion of the processing beam.

Abstract: A laser processing method and a laser processing system are provided. The laser processing method includes: irradiating a processing area of a workpiece with an electromagnetic wave; and after irradiating the processing area of the workpiece with the electromagnetic wave, irradiating the processing area of the workpiece with a processing pulse.

Abstract: This invention describes a small sized precision displacement sensor at sub-micron accuracy level with a cost of a fraction of those of existing commercial devices. The basic concept of the new sensor system is to apply a mechanical mechanism to magnify a sub-micron displacement to be measured so that the magnified displacement becomes within the measurement range of a low cost sensor such as a Hall sensor.

Abstract: A mid-infrared light emitting diode is provided, including a graphene lower electrode layer, a black phosphorous layer, and a graphene upper electrode layer sequentially arranged along a thickness direction of the mid-infrared light emitting diode, in which the black phosphorous layer contacts the graphene lower electrode layer and the graphene upper electrode layer. A manufacturing method of the mid-infrared light emitting diode, a silicon photonic circuit and a manufacturing method thereof are also provided.

Abstract: An image sensor integrated with a convolutional neural network computation circuit is provided. The image sensor includes: a pixel array including pixels divided into pixel groups, wherein each pixel converts a light signal into a PWM signal; a convolution computation circuit controlling a turn-on time of a corresponding weighted current according to the first PWM signal of each pixel, and accumulating the weighted currents into an integrated current; a comparison circuit converting the integrated current into a second PWM signal and comparing it with that of an adjacent pixel group to output a larger one; and a classification circuit quantizing the second PWM signal to a quantization value according to a weight of a node in a fully-connected layer corresponding to each pixel group, accumulating the quantization values of all pixel groups into a feature value, and comparing the feature value with a feature threshold to obtain a classification result.

Abstract: A solid-liquid contact electrification-based self-driving chemical sensor includes a container, a contact liquid, an electrode, a solid triboelectric layer, a rectifier, a load, and a displacement device. The contact liquid is placed in the container. The electrode may be actively or passively moved into the container to be immersed in or emerged from the contact liquid. The solid triboelectric layer surrounds and covers a surface of the electrode. The solid triboelectric layer includes a sensing layer which becomes a reacted sensing layer by reacting to a target analyte. The rectifier and the load are connected to the electrode. The displacement device is connected to the electrode or the container to perform a periodic reciprocating motion, so that the solid triboelectric layer is in contact with and separated from the contact liquid, thereby generating a surface charge transfer to generate an electrical output signal.

Abstract: A sensor device is adapted to detect glucose concentration in saliva of an object, and includes a conductive substrate, a polymer layer, and a carbon nanomaterial unit. The polymer layer is disposed on the conductive substrate and is made from conducting polymer. The carbon nanomaterial unit is disposed on the polymer layer and includes at least one carbon-nanotube layer. The saliva of the object is applied on the carbon nanomaterial unit and an enzyme is added to be mixed with the saliva to detect the glucose concentration in the saliva. A method for making the sensor device is also provided.

Abstract: Cell sorting methods are disclosed. A blood sample is provided. The blood sample is centrifuged to obtain a cell mixture having target cells and non-target cells. Fluorescent markers are added to the cell mixture to allow the fluorescent markers to bind with the target cells. A hydrogel solution is added and mixed with the cell mixture to form a mixture solution. The mixture solution is distributed to cell wells of an array chip, and the target cells and non-target cells in the cell mixture are spread on the bottom of the cell wells in a substantially monolayer manner. The mixture solution is cured. A fluorescence image analysis is performed to select the target cells that are bound with fluorescent markers and emit fluorescence, and the selected target cells are isolated.

Abstract: A ranging system includes: a source generating a wideband incident wave that is transmitted toward a target and that is reflected by the target to form a reflected wave; a feedback detector to detect the reflected wave to generate a detected signal; an operator configured to perform low-pass filtering on the detected signal at an adjustable filtering bandwidth to generate a filtered signal, and calculate cross-correlation of a feedback signal that originates from the filtered signal and a reference signal that corresponds to the incident wave to generate a cross-correlation result; and a controller calculating a distance to the target based on an operation output that originates from the cross-correlation result.

Abstract: A highly compressible shape memory double network hydrogel includes a first network and a second network interpenetrating with each other. The first network is a chemically crosslinked cellulose by chemical crosslinking, and the chemical crosslinking is accomplished by the formation of ether groups between the cellulose. The second network is a physically crosslinked alginate by physically crosslinking, and the physical crosslinking is accomplished by reaction of the alginate with divalent metal ions. In a preparation process of the highly compressible shape memory double network hydrogel, the cellulose and the alginate are mixed first, the chemical crosslinking is then performed to obtain the first network, followed by the physical crosslinking to obtain the second network.

Abstract: A sensing cell includes: a first electrode coupled to a gate of a transistor, a second electrode spaced apart from the first electrode; a protective layer covering sidewalls of the first electrode and the second electrode and having a first opening and a second opening exposing a first part of the first electrode and a second part of the second electrode, respectively; a first well located on the protective layer and surrounding the first electrode and the second electrode and having a third opening exposing the first part of the first electrode, the second part of the second electrode, and the protective layer between the first opening and the second opening; a second well located on the protective layer surrounding the first well and having a fourth opening to limit a flow of a liquid to be tested; and an ion selective membrane located in the third opening.

Abstract: A device for recognizing wafer identification number with automatically turning on and off recognizing function comprises a base, a support frame, a light source, a plurality of image capturing units, an image recognition unit and a control unit. The base comprises a wafer boat placing portion and a first switch disposed on the wafer boat placing portion. The light source and the image capturing units are disposed on the support frame. The control unit is electrically connected to the first switch, the light source, the image capturing units and the image recognition unit. As such, the device for recognizing wafer identification number with automatically turning on and off recognizing function can automatically turn on and off the light source, the image capturing units, and the image recognition unit, therefore the operation is very easy and convenience.

Abstract: A method and an apparatus for impact position detection of impact sport equipment are provided. The method includes following steps: retrieving a vibration signal generated by a vibration sensor detecting vibration caused by impact of impact sport equipment and a ball; performing a spectrum analysis on the vibration signal to obtain eigenfrequencies of the vibration signal in a frequency domain; and calculating at least one piece of characteristic information by using an amplitude of each eigenfrequency and inputting the same into a prediction model established in advance by using machine learning, so as to estimate an impact position of the ball on the impact sport equipment, in which the prediction model is trained by using characteristic information of multiple vibration signals and corresponding impact positions.