Electrolytic Etching/Deposition System. A system for continuous circuit fabrication comprising means for storing and dispensing the substrate, means for laminating the substrate, means for printing the substrate, means for optical inspection of the substrate, means for photolithography of the substrate, means for drying the substrate, means for developing the substrate, means for washing the substrate and means for electroplating the substrate.

A method includes: providing a first layout of a first layer over a substrate, the first layer having at least one metal pattern, and generating a second layout by placing a cut mask at a first position relative to the substrate to remove material from a first region of the at least one metal pattern to provide a first metal pattern and placing the cut mask at a second position relative to the first layer over the substrate to remove material from a second region of the at least one metal pattern to provide a second metal pattern.

Embodiments are directed to short and/or near short etch rework. A microfluidic device is positioned on a portion of a circuit having a defect. The microfluidic device is caused to dispense etchant that removes the defect of the circuit, where a flow of the etchant is controlled to access the portion of the circuit having the defect to thereby etch away the defect, the flow of the etchant being obstructed from accessing other portions of the circuit. The microfluidic device is used to extract the etchant from the portion of the circuit such that the etchant avoids contact with the other portions of the circuit. The microfluidic device is removed from the circuit.

The invention relates to a suction-extraction apparatus for extracting a treatment fluid by suction from an essentially planar treatment surface (3a) of treatment substrates (3) transported by means of transporting rollers (8, 10) along an essentially horizontal transporting direction, having a suction source, having a suction-extraction-control unit, which activates the same, and having a suction-extraction-tube unit, which is connected to the suction source and has at least one suction-extraction lance, which can have one or more entry-side suction-extraction-nozzle openings positioned at a suction-extraction distance from the treatment surface. The invention also relates to an etching apparatus equipped with such a suction-extraction apparatus. In the case of a suction-extraction apparatus according to the invention, the suction source and the suction-extraction-control unit are designed for a suction-volume flow per suction-extraction lance of at least 30 m.sup.3/h and a negative suction pressure of no more than 8 kPa. In addition, or as an alternative, the suction-extraction lance has a comb-like suction-extraction structure with a suction-extraction-collecting tube (17) and a plurality of suction-extraction tubes (18) which extend in a comb-like manner from said collecting tube and have the suction-extraction-nozzle openings (19) on the entry side. Use, for example, for etching printed circuit boards, conductor foils or semiconductor wafers.

Embodiments herein relate to creating a high-aspect ratio opening in a package. Embodiments may include applying a first laminate layer on a side of a substrate, applying a seed layer to at least part of the laminate layer, building up one or more copper pads on the seed layer, etching the seed layer to expose a portion of the first laminate layer, applying a second laminate layer to fill in around the sides of one or more copper pads, and removing part of the buildup copper pads. Other embodiments may be described and/or claimed.

A semi-automatic corrosion box of a copper clad laminate is disclosed. The corrosion device comprises a box body which has no cover; a baffle plate which divides the corrosion box into an upper part and a lower part, wherein a copper clad laminate circuit board is placed on the baffle plate, and a temperature detection module, water pumps and a heating rod are placed on a lower part; and a thermal imaging camera which is placed on a pressing plate through a bracket. Modules in corrosive liquid are connected with an external single chip microcomputer control module through corrosion-resistant wires. The working mode of the present invention is that time and temperature are set with a key matrix at first, and the control module can automatically stop working and enter a low power consumption mode.

Embodiments herein relate to creating a high-aspect ratio opening in a package. Embodiments may include applying a first laminate layer on a side of a substrate, applying a seed layer to at least part of the laminate layer, building up one or more copper pads on the seed layer, etching the seed layer to expose a portion of the first laminate layer, applying a second laminate layer to fill in around the sides of one or more copper pads, and removing part of the buildup copper pads. Other embodiments may be described and/or claimed.

A chemical engraving machine to engrave a plate of stainless steel moved along an horizontal direction, said machine comprising a base, an acid liquid circuit adapted to chemically attack said plate of stainless steel at locations where it is not protected by a protection mask, a lower guiding device, an upper guiding device, the lower and upper guiding devices being configured to maintain said plate of stainless steel substantially vertically, and a nozzle support bearing a plurality of spraying nozzles projecting horizontally the acid liquid toward the plate of stainless steel. A method chemically engraves a plate of stainless steel in a vertical position.

A method of making a device patterned with one or more electrically conductive features includes depositing a conductive material layer over an electrically insulating surface of a substrate, depositing an anti-corrosive material layer over the conductive material layer, and depositing an etch-resist material layer over the anti-corrosive material layer. The etch-resist material layer may be deposited over the anti-corrosive material layer, and the anti-corrosive material layer forming a bi-component etch mask in a pattern resulting in covered portions of the conductive material layer and exposed portions of the conductive material layer, the covered portions being positioned at locations corresponding to one or more conductive features of the device. A wet-etch process is performed to remove the exposed portions of the conductive material layer from the electrically insulating substrate, and the bi-component etch mask is removed to expose the remaining conductive material. Systems and devices relate to devices with patterned features.

The present invention relates to a process of oxidizing copper in a copper etching solution by using oxygen gas and/or air as an oxidizing agent, the process comprising the steps of: a) introducing the oxidizing agent into an acidic reduced copper etching solution comprising Cl.sup. and Cu.sup.+, b) stirring the solution obtained in step a), and thereby allowing the reaction 2Cu.sup.++O.sub.2 (aq)+2H.sup.+.fwdarw.2Cu.sup.2++H.sub.2O to occur, thereby producing an oxidized copper etching solution comprising less Cu.sup.+ than the reduced copper etching solution. An advantage of the present invention is that it provides an improved process at least in terms of the speed of the oxidation and the quality of the etching.