Thin film devices such as solar cells are typically patterned on substrates as thin films requiring that the devices be electrically isolated when arrays are formed and/or be mechanically separated for packaging. With the development of thin film processes based upon perovskite inks then large area substrates can be implemented. Further, such perovskite inks and their low temperature processing allow them to employ low temperature flexible and/or conformal substrates such as polymeric substrates for example. Accordingly, a requirement exists for electrical isolating and/or mechanically isolating thin film devices with different physical layer structures, different geometries etc. on a wide range of substrates.

A solar cell module comprises: two base plates each including a conductive layer on at least one side; and a plurality of submodules interposed between respective conductive layers of the two base plates. The plurality of submodules each include a plurality of cells connected to each other as a result of a conductive material electrically connecting the respective conductive layers of the two base plates. The two base plates each have a plurality of insulating grooves in a gap between the plurality of submodules. The plurality of insulating grooves of one of the two base plates and the plurality of insulating grooves of an other one of the two base plates define at least one insulating space that prevents short circuiting between adjacent submodules.

A solar cell module comprises: two base plates each including a conductive layer on at least one side; and a plurality of submodules interposed between respective conductive layers of the two base plates. The plurality of submodules each include a plurality of cells connected to each other as a result of a conductive material electrically connecting the respective conductive layers of the two base plates. The two base plates each have a plurality of insulating grooves in a gap between the plurality of submodules. The plurality of insulating grooves of one of the two base plates and the plurality of insulating grooves of an other one of the two base plates define at least one insulating space that prevents short circuiting between adjacent submodules.

In a thin film photoelectric conversion device fabricated by addition of a catalyst element with the use of a solid phase growth method, defects such as a short circuit or leakage of current are suppressed. A catalyst material which promotes crystallization of silicon is selectively added to a second silicon semiconductor layer formed over a first silicon semiconductor layer having one conductivity type, the second silicon semiconductor layer is partly crystallized by a heat treatment, a third silicon semiconductor layer having a conductivity type opposite to the one conductivity type is stacked, and element isolation is performed at a region in the second silicon semiconductor layer to which a catalyst material is not added, so that a left catalyst material is prevented from being diffused again, and defects such as a short circuit or leakage of current are suppressed.

Solar cells of varying composition are disclosed, generally including a central substrate, conductive layer(s), antireflection layers(s), passivation layer(s) and/or electrode(s). Multifunctional layers provide combined functions of passivation, transparency, sufficient conductivity for vertical carrier flow, the junction, and/or varying degrees of anti-reflectivity. Improved manufacturing methods including single-side CVD deposition processes and thermal treatment for layer formation and/or conversion are also disclosed.

Disclosed are a solar cell module and a method of fabricating the same. The solar cell module includes a back electrode layer disposed on a support substrate and having a first separation pattern, a light absorbing layer disposed on the back electrode layer and having a second separation pattern, and a plurality of solar cells disposed on the light absorbing layer and formed with a front electrode layer including an insulator.

A coating-removal apparatus may include a source positioned on a mounting plate, and operable to emit a laser beam at a first path, where the mounting plate is configured to receive an edge of a photovoltaic module in a designated region substantially proximate to the mounting plate, such that the first path intersects the designated region, and where the mounting plate is further configured to reposition the source to create an additional path that intersects with the designated region, where the additional path is distinct from the first path.

An apparatus for and a method of forming a plurality of groups of laser beams (2, 2, 2) are defined. Each group (2, 2, 2) may comprise two or more laser beams. The apparatus comprises a first diffractive optical element (3, referred as DOE) and a second diffractive optical element (8), the first DOE (3) being arranged to receive a first laser beam (1) and to divide this into a plurality of second laser sub-beams and the second DOE (8) being arranged to receive said plurality of second laser sub-beams and to divide each of these into two or more groups of third laser sub-beams (2, 2, 2), the separation of the groups in a direction perpendicular to a first axis being adjustable by rotation of the first DOE (3) about its optical axis and the separation of the third laser sub-beams (2, 2, 2) within each group in a direction perpendicular to the first axis being adjustable by rotation of the second DOE (8) about its optical axis.

A targeted-annealing system can automatically cure a conductive paste that may bind cascaded strips of a string together without damaging the strips. The targeted-annealing system can process strings of cascaded strips on a supporting surface, and can anneal conductive paste between overlapping strips by blowing heated air on the overlapping sections of the strips. An air nozzle shaped to target the overlapping sections may provide the heated air. The supporting surface may include a porous material that allows a vacuum to pull on the cascaded strips from below the surface during the annealing process.

A vertically selective liftoff scribing process is provided. One application is the fabrication of solar cells and solar modules. The basis of this technology is absorption of an indirectly focused laser beam in the front electrode material of the device, which enables removal of this layer (e.g., a P1 scribe) or removal of layers above the front electrode while leaving the front electrode intact (e.g., a P2 or P3 scribe). The laser fluence can be selected to choose between these alternatives, and further fine tuning is possible depending on details of the device structure.