A solar module assembly includes a frame having an upper portion encompassing an area and a mid portion disposed below the upper portion. A plurality of solar panels is arranged in a string, sandwiched between two transparent panes forming a single string panel. The solar panels occupy less than the area of the upper portion. Each of the plurality of solar panels has a pair of opposing edges. A reflector is mounted on the mid portion to reflect light selectively.

Metallization of semiconductor substrates using a laser beam, and the resulting structures, e.g., micro-electronic devices, semiconductor substrates and/or solar cells, solar cell circuit, solar cell strings, and solar cell arrays are described. A solar cell string can include a plurality of solar cells. The plurality of solar cells can include a substrate and a plurality of semiconductor regions disposed in or above the substrate. A plurality of conductive contact structures is electrically connected to the plurality semiconductor regions. Each conductive contact structure includes a locally deposited metal portion disposed in contact with a corresponding one of the semiconductor regions.

Metallization of semiconductor substrates using a laser beam, and the resulting structures, e.g., micro-electronic devices, semiconductor substrates and/or solar cells, solar cell circuit, solar cell strings, and solar cell arrays are described. A solar cell string can include a plurality of solar cells. The plurality of solar cells can include a substrate and a plurality of semiconductor regions disposed in or above the substrate. A plurality of conductive contact structures is electrically connected to the plurality semiconductor regions. Each conductive contact structure includes a locally deposited metal portion disposed in contact with a corresponding one of the semiconductor regions.

Multi-dimensional photonic integrated circuits are provided, including a substrate having a first side and a second side, a multi-dimensional package having multi-dimensional planes, and one or more optical components connected to the first side and the second side of the substrate and on the multi-dimensional planes of the multi-dimensional package. The multi-dimensional planes include one or more horizontal sides and one or more vertical sides. One or more of the optical components are mounted on at least one of the horizontal sides of the multi-dimensional package and one or more of the optical components are mounted on at least one of the vertical sides of the multi-dimensional package. Hybrid systems of conventional multi-dimensional integrated circuits and multi-dimensional photonic integrated circuits also are provided.

Multi-dimensional photonic integrated circuits are provided, including a substrate having a first side and a second side, a multi-dimensional package having multi-dimensional planes, and one or more optical components connected to the first side and the second side of the substrate and on the multi-dimensional planes of the multi-dimensional package. The multi-dimensional planes include one or more horizontal sides and one or more vertical sides. One or more of the optical components are mounted on at least one of the horizontal sides of the multi-dimensional package and one or more of the optical components are mounted on at least one of the vertical sides of the multi-dimensional package. Hybrid systems of conventional multi-dimensional integrated circuits and multi-dimensional photonic integrated circuits also are provided.

A floating body includes a main body having first and second surfaces opposite to each other and a first side surface connecting the first and second surfaces and first and second joining parts located on the first side surface to be opposite to each other in a first direction parallel to a ridge line defined by the first surface and the first side surface. The first and second joining parts each include a first portion located on the first side surface and a second portion connected to the first portion to face the first side surface. End portions of the first and second joining parts face each other. A minimum distance between the end portions is greater than twice a width of the second portion in the first direction, and is smaller than a minimum distance between the first portions of the first and second joining parts.

A photovoltaic module, having: a substrate, a plurality of photovoltaic structures that are electrically connected to one another and extend over the substrate, each of which comprises at least one photovoltaic cell, and a multilayer electrical connection structure sandwiched between the substrate and the plurality of photovoltaic structures, forming at least one bypass diode for each photovoltaic structure, each bypass diode having: two electrodes electrically connected to the terminals of opposite polarity of the corresponding photovoltaic structure, at least one of the two electrodes extending at least partially underneath the corresponding photovoltaic structure, and a semiconductor portion in contact with the two electrodes via two separate surfaces.

A photovoltaic module, having: a substrate, a plurality of photovoltaic structures that are electrically connected to one another and extend over the substrate, each of which comprises at least one photovoltaic cell, and a multilayer electrical connection structure sandwiched between the substrate and the plurality of photovoltaic structures, forming at least one bypass diode for each photovoltaic structure, each bypass diode having: two electrodes electrically connected to the terminals of opposite polarity of the corresponding photovoltaic structure, at least one of the two electrodes extending at least partially underneath the corresponding photovoltaic structure, and a semiconductor portion in contact with the two electrodes via two separate surfaces.

Provided is a solar cell for which accurate mutual alignment between a condenser lens and a power generating element corresponding thereto can be performed. In a solar cell 23, a plurality of grid electrodes 31 each formed in a linear shape are arrayed on a light receiving surface 23a along the width direction of the light receiving surface 23a. The plurality of grid electrodes 31 include a first center grid electrode 31a forming a cross portion 34 exhibiting a center-specific geometry caused by electrodes crossing each other at the center of the light receiving surface 23a.

Provided is a solar cell for which accurate mutual alignment between a condenser lens and a power generating element corresponding thereto can be performed. In a solar cell 23, a plurality of grid electrodes 31 each formed in a linear shape are arrayed on a light receiving surface 23a along the width direction of the light receiving surface 23a. The plurality of grid electrodes 31 include a first center grid electrode 31a forming a cross portion 34 exhibiting a center-specific geometry caused by electrodes crossing each other at the center of the light receiving surface 23a.