Abstract: A cyclical epitaxial deposition system and a gas distribution module are provided. The gas distribution module includes an inflow element having a plurality of inlet holes, a guide assembly, and an outflow element. The guide assembly disposed between the inflow and outflow elements includes a plurality of guide channels separate from one another and a plurality of temporary gas retention trenches respectively corresponding to the guide channels. Each of the guide channels is in fluid communication with the corresponding inlet hole. The outflow element has a plurality of diffusion regions respectively corresponding to the gas retention trenches, and a plurality of outlet channels respectively corresponding to the diffusion regions. Each of the diffusion regions has a plurality of diffusion apertures, and each of the temporary gas retention trenches is in fluid communication with the corresponding outlet channel through the diffusion apertures in the corresponding diffusion region.

Abstract: A cyclical epitaxial deposition system is provided. The cyclical epitaxial deposition system includes a deposition chamber, a conveyance device, and a gas distribution module. The conveyance device is used to continuously convey a substrate to pass through the deposition chamber along a conveyance path. The gas distribution module is disposed in the deposition chamber and located above the conveyance path. The gas distribution module includes a plurality of precursor gas nozzles and purge gas nozzles that are not in communication with one another so as to guide at least one precursor gas and at least one purge gas to different regions of the substrate at the same time.

Abstract: A cyclical epitaxial deposition system and a gas distribution module are provided. The gas distribution module includes an inflow element having a plurality of inlet holes, a guide assembly, and an outflow element. The guide assembly disposed between the inflow and outflow elements includes a plurality of guide channels separate from one another and a plurality of temporary gas retention trenches respectively corresponding to the guide channels. Each of the guide channels is in fluid communication with the corresponding inlet hole. The outflow element has a plurality of diffusion regions respectively corresponding to the gas retention trenches, and a plurality of outlet channels respectively corresponding to the diffusion regions. Each of the diffusion regions has a plurality of diffusion apertures, and each of the temporary gas retention trenches is in fluid communication with the corresponding outlet channel through the diffusion apertures in the corresponding diffusion region.

Abstract: An electromagnetic wave charge management circuit includes: an antenna to receive an electromagnetic wave signal; a filtering unit electrically connected to the antenna to filter the electromagnetic wave signal received by the antenna; a converting unit electrically connected to the filtering unit to convert the filtered electromagnetic wave signal by the filtering unit into a direct current voltage; a charging unit electrically connected to the converting unit to provide the direct current voltage generated by the converting unit to an internal power supplier of the receiver device; and a controlling unit electrically connected to the filtering unit and the charging unit to transmit a first control signal that is for controlling the filtering unit to filter the electromagnetic wave signal, and a second control signal that is for controlling the charging unit to provide the direct current voltage generated by the converting unit to the internal power supplier.

Abstract: An electricity management method of wireless charging includes: detecting a charging request signal sent by a receiver device; selecting a transmitter device according to a location of the receiver device; detecting the location of the receiver device and a plurality of micro-electrometric wave charging environmental parameters thereof; collecting a strength distribution of a micro-electrometric wave signal frequency band in an area where the transmitter device is located, and transmitting area charging performance information based on the strength distribution of the micro-electrometric wave signal frequency band and area information of the area where the transmitter device is located; selecting one of the plurality of charging modes based on the charging request signal and the micro-electrometric wave charging environmental parameters; and based on the selected charging mode, controlling the transmitter device to turn on a charging function corresponding to the receiver device to charge the receiver device.

Abstract: A rechargeable battery and an electrode thereof are provided. The rechargeable battery includes two electrodes and an ionic conduction layer. The ionic conduction layer is disposed between the two electrodes. At least one electrode includes a diffusion-assisting structure facing to the ionic conduction layer. The diffusion-assisting structure has a concaved pattern.

Abstract: An electricity management method of wireless charging includes: detecting a charging request signal sent by a receiver device; selecting a transmitter device according to a location of the receiver device; detecting the location of the receiver device and a plurality of micro-electrometric wave charging environmental parameters thereof; collecting a strength distribution of a micro-electrometric wave signal frequency band in an area where the transmitter device is located, and transmitting area charging performance information based on the strength distribution of the micro-electrometric wave signal frequency band and area information of the area where the transmitter device is located; selecting one of the plurality of charging modes based on the charging request signal and the micro-electrometric wave charging environmental parameters; and based on the selected charging mode, controlling the transmitter device to turn on a charging function corresponding to the receiver device to charge the receiver device.

Abstract: A rechargeable battery and an electrode thereof are provided. The rechargeable battery includes two electrodes and an ionic conduction layer. The ionic conduction layer is disposed between the two electrodes. At least one electrode includes a diffusion-assisting structure facing to the ionic conduction layer. The diffusion-assisting structure has a concaved pattern.

Abstract: An electromagnetic wave charge management circuit includes: an antenna to receive an electromagnetic wave signal; a filtering unit electrically connected to the antenna to filter the electromagnetic wave signal received by the antenna; a converting unit electrically connected to the filtering unit to convert the filtered electromagnetic wave signal by the filtering unit into a direct current voltage; a charging unit electrically connected to the converting unit to provide the direct current voltage generated by the converting unit to an internal power supplier of the receiver device; and a controlling unit electrically connected to the filtering unit and the charging unit to transmit a first control signal that is for controlling the filtering unit to filter the electromagnetic wave signal, and a second control signal that is for controlling the charging unit to provide the direct current voltage generated by the converting unit to the internal power supplier.