A display includes a plurality of pixel chips, chixels, provided on a substrate. The chixels and the light emitters thereon may be shaped, sized and arranged to minimize chixel, pixel, and sub-pixel gaps and to provide a seamless look between adjacent display modules. The substrate may include light manipulators, such as filters, light converters and the like to manipulate the light emitted from light emitters of the chixels. The light manipulators may be arranged to minimize chixel gaps between adjacent chixels.

A vacuum processing system for a flexible substrate is provided. The vacuum processing system includes a first chamber adapted for housing a supply roll for providing the flexible substrate; a second chamber adapted for housing a take-up roll for storing the flexible substrate after processing; a substrate transport arrangement including one or more guide rollers for guiding the flexible substrate from the first chamber to the second chamber; a maintenance zone between the first chamber and the second chamber wherein the maintenance zone allows for maintenance access to or of at least one of the first chamber and the second chamber; and a first process chamber for processing the flexible substrate.

The present disclosure provides a method and system for manufacturing solar cells and shingled solar cell modules. The method as provided by the present disclosure includes performing scribing and dividing of the solar cells, sorting the obtained solar cell strips, and packaging the cell strips in the solar cell manufacturing process. The solar cell strips can be assembled directly after dismantling the package in the solar module manufacturing process. Therefore, the method can accomplish a smooth flow of manufacturing solar cells and shingled solar cell modules, reduce repeated processing steps, lower the risk of cracking and costs thereof, and optimize the current matching and the color consistency of the cell strips in the shingled solar cell modules.

A method is disclosed for applying an electrical conductor to a solar cell, which comprises providing a flexible membrane with a pattern of groove formed on a first surface thereof, and loading the grooves with a composition comprising conductive particles. The composition is, or may be made, electrically conductive. Once the membrane is loaded, the grooved first surface of the membrane is brought into contact with a front or/and back of a solar cell. A pressure is then applied between the solar cell and the membrane(s) so that the composition loaded to the grooves adheres to the solar cell. The membrane(s) and the solar cell are separated and the composition in the groove is left on the solar cell surface. The electrically conductive particles in the composition are then sintered or otherwise fused to form a pattern of electrical conductor on the solar cell, the pattern corresponding to the pattern formed in the membrane(s).

A method is disclosed for applying an electrical conductor to an electrically insulating substrate, which comprises providing a flexible membrane with a pattern of groove formed on a first surface thereof, and loading the grooves with a composition comprising conductive particles. The composition is, or may be made, electrically conductive. Once the membrane is loaded, the grooved first surface of the membrane is brought into contact with a front or/and back of the substrate. A pressure is then applied between the substrate and the membrane(s) so that the composition loaded to the grooves adheres to the substrate. The membrane(s) and the substrate are separated and the composition in the groove is left on the surface of the electrically insulating substrate. The electrically conductive particles in the composition are then sintered to form a pattern of electrical conductors on the substrate, the pattern corresponding to the pattern formed in the membrane(s).

A display includes a plurality of pixel chips, chixels, provided on a substrate. The chixels and the light emitters thereon may be shaped, sized and arranged to minimize chixel, pixel, and sub-pixel gaps and to provide a seamless look between adjacent display modules. The substrate may include light manipulators, such as filters, light converters and the like to manipulate the light emitted from light emitters of the chixels. The light manipulators may be arranged to minimize chixel gaps between adjacent chixels.

An ion beam treatment or implantation system includes an ion source emitting a plurality of parallel ion beams having a given spacing. A first lens magnet having a non-uniform magnetic field receives the plurality of ion beams from the ion source and focuses the plurality of ion beams toward a common point. The system may optionally include a second lens magnet having a non-uniform magnetic field receiving the ion beams focused by the first lens magnet and redirecting the ion beams such that they have a parallel arrangement having a closer spacing than said given spacing in a direction toward a target substrate.

A processing system and a processing method are provided that allows for convenient and easy, roll-to-roll processing of both sides of a substrate at atmospheric pressure. A system of processing a substrate using mist or droplets containing a processing agent, wherein the mist or droplets is allowed to be retained and the substrate is processed by impregnating with the retained mist or droplets using a processing device including a retaining section that retains the mist or droplets and an impregnation section that impregnates the substrate with the mist or droplets.

A shielded sputter deposition system and method, the system including a process module including: a vacuum enclosure configured to receive a moving substrate, sputtering targets disposed in the vacuum enclosure, each sputtering target including a target material, and a peripheral shield disposed between the and substrate and an interstitial space located between adjacent sputtering targets. The peripheral shield may be configured to at least partially block indirect deposition of sputtered target material onto the substrate and to permit direct deposition of the sputtered target material onto the substrate.

A semiconductor system includes a silicon substrate and a porous silicon region disposed on the silicon substrate. The porous silicon region is configured to passivate the surface of the silicon substrate via a field effect and to reduce reflection loss on the silicon substrate via an appropriate refractive index. The porous silicon region is manufactured by a stain etching process, which retrofits existing tools for junction isolation and Phosphorus Silicon Glass (PSG) etch in solar cell manufacturing. The retrofitted tools for junction isolation and PSG etch achieves multiple purposes in a single step, including etch-back, PSG etch, antireflection coating, and passivation of the front surface of the solar cell.