A method for producing a silicon ingot, provided with symmetrical grain boundaries, including at least steps made of: (i) providing crucible with longitudinal axis, bottom of which includes a paving formed from monocrystalline cuboid silicon seeds with a square or rectangular base and arranged contiguously, the paving, when viewed according to axis, being in shape of a grid of orthogonal directions (x) and (y) parallel to edges of seeds; and (ii) proceeding with controlled solidification of silicon by growth on seeds in a growth direction collinear to axis; wherein paving in step (i) is produced from identical silicon seeds, with two seeds contiguous in direction (x) being images of each other by turning axis (y) and two seeds contiguous in direction (y) being images of each other by turning axis (x), and misorientation 2 between crystalline arrays of two contiguous seeds being greater than 4.

A method for producing a silicon ingot, provided with symmetrical grain boundaries, including at least steps made of: (i) providing crucible with longitudinal axis, bottom of which includes a paving formed from monocrystalline cuboid silicon seeds with a square or rectangular base and arranged contiguously, the paving, when viewed according to axis, being in shape of a grid of orthogonal directions (x) and (y) parallel to edges of seeds; and (ii) proceeding with controlled solidification of silicon by growth on seeds in a growth direction collinear to axis; wherein paving in step (i) is produced from identical silicon seeds, with two seeds contiguous in direction (x) being images of each other by turning axis (y) and two seeds contiguous in direction (y) being images of each other by turning axis (x), and misorientation 2 between crystalline arrays of two contiguous seeds being greater than 4.

Systems and methods for growing high-quality CdTe-based materials at high growth rates are provided. According to an aspect of the invention, a method includes depositing a first CdTe-based layer on a CdTe-based template at a rate of greater than 1 m/min. Each of the first CdTe-based layer and the CdTe-based template has a single-crystal structure and/or a large-grain polycrystalline structure. The depositing is performed by physical vapor deposition.

A method for manufacturing a silicon cylinder by growth on seeds in a directed solidification furnace, including at least the following steps: (i) providing a crucible having a longitudinal axis (Z), in which the bottom is covered with a layer of seeds of monocrystalline silicon in a right prism shape; and (ii) proceeding with directed solidification of silicon by growth on seeds, in a direction of growth that is co-linear with the axis (Z) and with a concave solidification front, spatially or temporally; characterized in that the layer in step (i) of: one or more central seeds G.sub.c; and one or more peripheral seeds G.sub.p contiguous to the seed(s) G.sub.c, the peripheral seeds G.sub.p having a specific size.

A method for manufacturing a silicon cylinder by growth on seeds in a directed solidification furnace, including at least the following steps: (i) providing a crucible having a longitudinal axis (Z), in which the bottom is covered with a layer of seeds of monocrystalline silicon in a right prism shape; and (ii) proceeding with directed solidification of silicon by growth on seeds, in a direction of growth that is co-linear with the axis (Z) and with a concave solidification front, spatially or temporally; characterized in that the layer in step (i) of: one or more central seeds G.sub.c; and one or more peripheral seeds G.sub.p contiguous to the seed(s) G.sub.c, the peripheral seeds G.sub.p having a specific size.

A hybrid crucible comprising a frame and a bottom plate. The crucible is characterized by the selection of material of these two components, which have been optimized in terms of thermal conductivity. The crucible is adapted to produce crystalline materials. Moreover, a method for producing crystalline material is disclosed.

A hybrid crucible comprising a frame and a bottom plate. The crucible is characterized by the selection of material of these two components, which have been optimized in terms of thermal conductivity. The crucible is adapted to produce crystalline materials. Moreover, a method for producing crystalline material is disclosed.

A SiC single crystal having high crystallinity and a large diameter is provided. A SiC single crystal comprising a seed crystal with a c-plane and a non-c-plane, and a c-plane growth portion and an enlarged diameter portion that have grown from the c-plane and the non-c-plane of the seed crystal as origins in the direction of the c-plane and the direction of the non-c-plane, wherein a continuous region free of threading dislocations is present in a peripheral portion of a plane that is parallel to the c-plane of the seed crystal, and contains the seed crystal and the enlarged diameter portion, wherein the area of the continuous region occupies 50% or more of the total area of the plane.

A SiC single crystal having high crystallinity and a large diameter is provided. A SiC single crystal comprising a seed crystal with a c-plane and a non-c-plane, and a c-plane growth portion and an enlarged diameter portion that have grown from the c-plane and the non-c-plane of the seed crystal as origins in the direction of the c-plane and the direction of the non-c-plane, wherein a continuous region free of threading dislocations is present in a peripheral portion of a plane that is parallel to the c-plane of the seed crystal, and contains the seed crystal and the enlarged diameter portion, wherein the area of the continuous region occupies 50% or more of the total area of the plane.

A method of fabricating a poly-crystalline silicon ingot includes: (a) loading a nucleation promotion layer onto a bottom of a mold; (b) providing a silicon source on the nucleation promotion layer in the mold; (c) heating the mold until the silicon source is melted into a silicon melt completely; (d) controlling at least one thermal control parameter regarding the silicon melt continually to enable the silicon melt to nucleate on the nucleation promotion layer such that a plurality of silicon grains grow in the vertical direction; (e) controlling the at least one thermal control parameter to enable the plurality of the silicon grains to continuously grow with an average grain size increasing progressively in the vertical direction until entirety of the silicon melt is solidified to obtain the poly-crystalline silicon ingot, wherein the nucleation promotion layer is loaded by spreading a plurality of mono-Si particles over the bottom of the mold.