Abstract: A magnetic assembly is provided, including an annular main magnetic element and an annular axillary magnetic element. The main magnetic element has a plurality of main magnetic segments of different polar directions and lengths. The axillary magnetic element has a plurality of axillary magnetic segments of different polar directions and lengths, corresponding to the main magnetic segments.

Abstract: An electromagnetic loss film includes a magnetic oxide film body and a plurality of electromagnetic loss structures. The magnetic oxide film body corresponds to a magnetic response frequency (FR), and the range of the magnetic response frequency is 0.1 MHz?FR?300 GHz. The electromagnetic loss structures are formed in the magnetic oxide film body, and the electromagnetic loss structures penetrate or are recessed in the magnetic oxide film body. Each of the electromagnetic loss structures has a long diameter, and the long diameter is N1x light velocity/FR, and 0.005?N1?1, and a space between the electromagnetic loss structures is N2x light velocity/FR, wherein 0.005?N2?1, and N1<N2.

Abstract: The disclosure provides a manufacturing method of a mass transfer device. The manufacturing method includes the following. A transfer substrate coated with an adhesive layer is provided. A light emitting diode is transferred from an original substrate to the transfer substrate. A supporting structure is etched on the light emitting diode, where the supporting structure includes at least two supporting columns extending from the transfer substrate, and ends of the at least two supporting columns away from the transfer substrate are connected with the light emitting diode, so that the light emitting diode is arranged separately from the transfer substrate. The adhesive layer is removed, so that the light emitting diode is fixed on the transfer substrate only through the supporting structure. In addition, the disclosure also provides a mass transfer device and display equipment.

Abstract: An electromagnetic wave absorber including a substrate and a plurality of magnetic material bodies is provided. The plurality of magnetic material bodies are disposed on the substrate in an array, so that the electromagnetic wave absorber has a plurality of electromagnetic wave absorption frequencies in addition to an electromagnetic wave characteristic frequency of the plurality of magnetic material bodies. A ratio of one of the plurality of electromagnetic wave absorption frequencies to the electromagnetic wave characteristic frequency is greater than 1 and is less than or equal to 6.

Abstract: Disclosed are methods and compositions for treating cell proliferative diseases and disorders such as cancers. Particularly disclosed are methods and composition for treating cancers such as glioblastoma by administering a therapeutic agent that inhibits the biological activity of the autophagy related 4B cysteine peptidase (ATG4B) protein in conjunction with additional therapeutic agents or treatments.

Abstract: An electrostatic sensing system configured to sense an electrostatic information of a fluid inside a fluid distribution component and including an electrostatic sensing assembly, a signal amplifier and an analog-to-digital converter. The electrostatic sensing assembly includes a sensing component, and a shield. The sensing component is configured to be disposed at the fluid distribution component. The sensing component is disposed through the fluid distribution component so as to be partially located in the fluid distribution component. The shield surrounds a part of the sensing component that is located in the fluid distribution component. At least part of the shield is located on an upstream side of the sensing component. The signal amplifier is electrically connected to the sensing component. The analog-to-digital converter is electrically connected to the signal amplifier. The shield has an opening spaced apart from the sensing component.

Abstract: Disclosed are methods and compositions for treating cell proliferative diseases and disorders such as cancers. Particularly disclosed are methods and composition for treating cancers such as glioblastoma by administering a therapeutic agent that inhibits the biological activity of the autophagy related 4B cysteine peptidase (ATG4B) protein in conjunction with additional therapeutic agents or treatments.

Abstract: A magnetic field structure is provided and includes: two magnetic poles disposed in a magnetic circuit path and opposite to one another to form a space therebetween for receiving an element to be tested; a magnetic field source for providing a magnetic field in the space; and an optical positioning element disposed in one of the two magnetic poles for optically positioning the element to be tested. Therefore, the magnetic field structure can simultaneously provide a strong magnetic field and a precise positioning function.

Abstract: The present disclosure provides an electromagnetic wave absorbing material, including a core containing iron oxide having a first thermal expansion coefficient; and a shell layer covering the core, which has a second thermal expansion coefficient less than the first thermal expansion coefficient, and the shell layer contains an inorganic compound selected from a group consisting of oxides, nitrides or any combination thereof. The present disclosure further provides a composite structure for suppressing electromagnetic interference including the electromagnetic wave absorbing material as claimed.

Abstract: A cover plate used in an electronic device includes a glass layer and at least one transparent covering layer. The glass layer has a first surface and a second surface. The transparent covering layer contacts and is disposed on at least one of the first surface and the second surface, and the transparent covering layer is laminated with the glass layer. The cover plate has a Young's modulus of about 10 GPa to about 200 GPa.

Abstract: An electromagnetic property measuring device includes a magnetic conductive structure, a coil, and a scattering parameter measuring unit. The magnetic conductive structure includes a first side facing a sample to be tested and a second side opposite to the first side, and the first side has a magnetic gap. The coil surrounds the magnetic conductive structure to generate a magnetic field with the magnetic conductive structure. The scattering parameter measuring unit is disposed at the first side and located within a range of the magnetic field.

Abstract: An electronic device includes a substrate, a polarizer, a flexible printed circuit board, a first transparent glue layer, a first colloid, and a second colloid. The substrate includes a first side and a second side. The first side is opposite to the second side. The polarizer is disposed on the first side of the substrate. The flexible printed circuit board is connected to the first side of the substrate with a conductive glue. A gap is formed between flexible circuit board and polarizer. The first transparent glue layer is disposed on the second side of substrate. The first colloid is configured to bond at least two of substrate, polarizer, or flexible printed circuit board. The second colloid is configured to bond at least two of the substrate, the flexible printed circuit board, or the first transparent glue layer. The first colloid is not in contact with the second colloid.

Abstract: An electronic device includes a substrate, a polarizer, a flexible printed circuit board, a first transparent glue layer, a first colloid, and a second colloid. The substrate includes a first side and a second side. The first side is opposite to the second side. The polarizer is disposed on the first side of the substrate. The flexible printed circuit board is connected to the first side of the substrate with a conductive glue. A gap is formed between flexible circuit board and polarizer. The first transparent glue layer is disposed on the second side of substrate. The first colloid is configured to bond at least two of substrate, polarizer, or flexible printed circuit board. The second colloid is configured to bond at least two of the substrate, the flexible printed circuit board, or the first transparent glue layer. The first colloid is not in contact with the second colloid.

Abstract: A cover plate used in an electronic device includes a glass layer and at least one transparent covering layer. The glass layer has a first surface and a second surface. The transparent covering layer contacts and is disposed on at least one of the first surface and the second surface, and the transparent covering layer is laminated with the glass layer. The cover plate has a Young's modulus of about 10 GPa to about 200 GPa.

Abstract: A magnetic field structure is provided and includes: two magnetic poles disposed in a magnetic circuit path and opposite to one another to form a space therebetween for receiving an element to be tested; a magnetic field source for providing a magnetic field in the space; and an optical positioning element disposed in one of the two magnetic poles for optically positioning the element to be tested. Therefore, the magnetic field structure can simultaneously provide a strong magnetic field and a precise positioning function.

Abstract: The disclosure provides a manufacturing method of a mass transfer device. The manufacturing method includes the following. A transfer substrate coated with an adhesive layer is provided. A light emitting diode is transferred from an original substrate to the transfer substrate. A supporting structure is etched on the light emitting diode, where the supporting structure includes at least two supporting columns extending from the transfer substrate, and ends of the at least two supporting columns away from the transfer substrate are connected with the light emitting diode, so that the light emitting diode is arranged separately from the transfer substrate. The adhesive layer is removed, so that the light emitting diode is fixed on the transfer substrate only through the supporting structure. In addition, the disclosure also provides a mass transfer device and display equipment.

Abstract: An electrostatic sensing system configured to sense an electrostatic information of a fluid inside a fluid distribution component and including an electrostatic sensing assembly, a signal amplifier and an analog-to-digital converter. The electrostatic sensing assembly includes a sensing component, and a shield. The sensing component is configured to be disposed at the fluid distribution component. The sensing component is disposed through the fluid distribution component so as to be partially located in the fluid distribution component. The shield surrounds a part of the sensing component that is located in the fluid distribution component. At least part of the shield is located on an upstream side of the sensing component. The signal amplifier is electrically connected to the sensing component. The analog-to-digital converter is electrically connected to the signal amplifier. The shield has an opening spaced apart from the sensing component.

Abstract: An electromagnetic property measuring device includes a magnetic conductive structure, a coil, and a scattering parameter measuring unit. The magnetic conductive structure includes a first side facing a sample to be tested and a second side opposite to the first side, and the first side has a magnetic gap. The coil surrounds the magnetic conductive structure to generate a magnetic field with the magnetic conductive structure. The scattering parameter measuring unit is disposed at the first side and located within a range of the magnetic field.

Abstract: Disclosed are methods and compositions for treating cell proliferative diseases and disorders such as cancers. Particularly disclosed are methods and composition for treating cancers such as glioblastoma by administering a therapeutic agent that inhibits the biological activity of the autophagy related 4B cysteine peptidase (ATG4B) protein in conjunction with additional therapeutic agents or treatments.

Abstract: An electrostatic detecting device adapted to an object. The electrostatic detecting device includes a substrate, a sensing electrode, a dielectric layer and a ground electrode. The substrate has a first surface and a second surface opposite to the first surface. The sensing electrode is disposed on the first surface and has a sensing surface. The sensing surface faces away from the first surface and configured to face the object. The dielectric layer having a dielectric constant greater than 1 is disposed on the second surface. The ground electrode is disposed apart from the sensing electrode by a spacing. The dielectric layer is disposed between the sensing electrode and the ground electrode.