The disclosure relates to microchemical (or microfluidic) apparatus as well as related methods for making the same. The methods generally include partial sintering of sintering powder (e.g., binderless or otherwise free-flowing sintering powder) that encloses a fugitive phase material having a shape corresponding to a desired cavity structure in the formed apparatus. Partial sintering removes the fugitive phase and produces a porous compact, which can then be machined if desired and then further fully sintered to form the final apparatus. The process can produce apparatus with small, controllable cavities shaped as desired for various microchemical or microfluidic unit operations, with a generally smooth interior cavity finish, and with materials (e.g., ceramics) able to withstand harsh environments for such unit operations.

In a method for manufacturing ceramic substrates and module components, an unfired mother ceramic substrate is cut at predetermined positions for division into separate unfired ceramic substrates. The cut unfired mother ceramic substrate is pressed such that pressure is applied parallel or substantially parallel to its main surfaces so that the cross-sectional end surfaces created in the cutting step are joined. The unfired mother ceramic substrate including end surface junctions, resulting from joining of the cross-sectional end surfaces, is fired. The fired mother ceramic substrate is broken along the end surface junctions to divide it into separate ceramic substrates.

A method of manufacturing a ceramics-metal bonded body according to the present invention is a method of manufacturing a ceramics-metal bonded body in which a metal layer is bonded to at least one surface of a ceramics substrate, and comprises: a groove-forming step of forming a groove extending across a bonding region of a ceramics substrate to which a metal layer is bonded; and a bonding step of, after the groove-forming step, forming a metal layer by stacking, in the bonding region of the ceramics substrate, a metal plate of an aluminum or aluminum alloy with a thickness of less than or equal to 0.4 mm, via an Al—Si based brazing material foil, and bonding the metal plate to the bonding region by heating while applying load in a stacking direction.

An impact resistant panel used to replace spandrel glass panels or aluminum panels in structures that uses an impact resistant interlayer to fuse two porcelain layers together. The panel of the present invention is a three-layered panel formed by fusing a first rolled porcelain layer, an impact resistant interlayer and a second rolled porcelain layer. The impact resistant interlayer is melted into the pores of the porcelain layers to create an integral porcelain panel that can be used as structural elements or small, medium, and large dimensions while having impact resistant qualities.

A shower plate according to the present disclosure includes a ceramic sintered body, the ceramic sintered body comprising a first surface, a second surface facing the first surface, and a through hole positioned between the first surface and the second surface. An inner surface of the through hole includes a protruding crystal grain which protrudes more than an exposed part of a grain boundary phase existing between crystal grains. In addition, a semiconductor manufacturing apparatus according to the present disclosure includes the shower plate mentioned above.

An assembly includes a first member, a second member adjacent to the first member, and an aluminum material. At least one of the first member and the second member defines at least one trench. The aluminum material is disposed within the trench and bonds the first member to the second member along adjacent faces. A spacing between the first member and the second member along the adjacent faces is less than 5 m and a surface roughness of the adjacent faces of the first and second ceramic members is between 5 mm and 100 nanometers.

The disclosure relates to microchemical (or microfluidic) apparatus as well as related methods for making the same. The methods generally include partial sintering of sintering powder (e.g., binderless or otherwise free-flowing sintering powder) that encloses a fugitive phase material having a shape corresponding to a desired cavity structure in the formed apparatus. Partial sintering removes the fugitive phase and produces a porous compact, which can then be machined if desired and then further fully sintered to form the final apparatus. The process can produce apparatus with small, controllable cavities shaped as desired for various microchemical or microfluidic unit operations, with a generally smooth interior cavity finish, and with materials (e.g., ceramics) able to withstand harsh environments for such unit operations.

The disclosure relates to microchemical (or microfluidic) apparatus as well as related methods for making the same. The methods generally include partial sintering of sintering powder (e.g., binderless or otherwise free-flowing sintering powder) that encloses a fugitive phase material having a shape corresponding to a desired cavity structure in the formed apparatus. Partial sintering removes the fugitive phase and produces a porous compact, which can then be machined if desired and then further fully sintered to form the final apparatus. The process can produce apparatus with small, controllable cavities shaped as desired for various microchemical or microfluidic unit operations, with a generally smooth interior cavity finish, and with materials (e.g., ceramics) able to withstand harsh environments for such unit operations.

The present invention provides a method for manufacturing a ceramic electrostatic chuck which enables high purity and minimum thickness variation of a dielectric layer formed of ceramics or composite ceramics. The method includes: forming grooves for electrode pattern formation in a dielectric layer formed of ceramics or composite ceramics and having a density of 95% or greater; forming an electrode pattern by filling the grooves with a metal; forming an activated bonding layer configured for joining on the dielectric layer; and joining an insulator layer, which is formed of ceramics or composite ceramics and has a density of 95% or greater, with the dielectric layer.

An assembly includes a first member, a second member adjacent to the first member, and an aluminum material. At least one of the first member and the second member defines at least one trench. The aluminum material is disposed within the trench and bonds the first member to the second member along adjacent faces. In one form, a spacing between the first member and the second member along the adjacent faces is less than 5 m.