Abstract: Disclosed herein are methods of preparing vertical electrical interconnects within multiple layers of substrates, where a portion of the substrate layers are glass and a portion of the substrate layers are single-crystal silicon. The methods taught herein can be used to prepare basic “units” which can be stacked and anodically bonded together to form electrically connected, multi-unit structures. The methods of the invention are particularly advantageous in the fabrication of microcolumns, and especially an array of microcolumns of the kind used in electron optics, including electron microscopes and lithography apparatus.

Abstract: We disclose a method of applying a sculptured layer of material on a semiconductor feature surface using ion deposition sputtering, wherein a surface onto which the sculptured layer is applied is protected to resist erosion and contamination by impacting ions of a depositing layer. A first protective layer of material is deposited on a substrate surface using traditional sputtering or ion deposition sputtering, in combination with sufficiently low substrate bias that a surface onto which the layer is applied is not eroded away or contaminated during deposition of the protective layer. Subsequently, a sculptured second layer of material is applied using ion deposition sputtering at an increased substrate bias, to sculpture a shape from a portion of the first protective layer of material and the second layer of depositing material. The method is particularly applicable to the sculpturing of barrier layers, wetting layers, and conductive layers upon semiconductor feature surfaces.

Abstract: Disclosed herein is a method of etching a trench in silicon overlying a dielectric material which reduces or substantially eliminates notching at the base of the trench, while reducing scalloping on the sidewalls of the trench. The method comprises etching a first portion of a trench by exposing a silicon substrate, through a patterned masking layer, to a plasma generated from a fluorine-containing gas. This etching is followed by a polymer deposition step comprising exposing the substrate to a plasma generated from a gas which is capable of forming a polymer on etched silicon surfaces. The etching and polymer deposition steps are repeated for a number of cycles, depending on the desired depth of the first portion of the trench. The final portion of the trench is etched by exposing the silicon to a plasma generated from a combination of a fluorine-containing gas and a polymer-forming gas.

Abstract: We have developed a method of selectively etching silicon nitride relative to oxides in a high density plasma chamber of the kind presently known in the art. We have obtained selectivities for silicon nitride:silicon oxide in the range of about 15:1 to about 24:1. We have employed the method in the etching of silicon nitride spacers for sub 0.25 &mgr;m devices, where the spacers are adjacent to exposed oxides during the etch process. We have obtained silicon nitride spacers having rounded top corners and an extended “tail” toward the bottom outer edge of the nitride spacer. The method employs a plasma source gas which typically includes SF6, HBr, N2 and optionally, O2. Typically, the pressure in the etch chamber during etching is at least 35 mTorr and the substrate temperature is about 20° C. or less.

Abstract: A method of etching a platinum electrode layer disposed on a substrate to produce a semiconductor device including a plurality of platinum electrodes. The method comprises heating the substrate to a temperature greater than about 150° C., and etching the platinum electrode layer by employing a plasma of an etchant gas comprising nitrogen and a halogen (e.g. chlorine), and a gas selected from the group consisting of a noble gas (e.g. argon), BCl3, HBr, SiCl4 and mixtures thereof. The substrate may be heated in a reactor chamber having a dielectric window including a deposit-receiving surface having a surface finish comprising a peak-to-valley roughness height with an average height value of greater than about 1000 Å.

Abstract: A method for forming a mask assembly for use in lithography, typically electron-beam lithography, first forms in a substrate one half of a plurality of opening therethrough and then fills the openings with a removable fill material. Thereafter are formed the other half of the openings which are then filled with the removable fill material. After all the openings have been formed and filled, a support membrane is formed over the substrate and covers the filled windows. A mask layer is then formed over the membrane and patterned. The fill is then removed from all of the windows.

Abstract: Disclosed is a method of forming a thick silicon oxide layer upon or internal to a silicon structure. The method is particularly useful in creating isolation regions within a silicon-containing structure, where such isolation regions can withstand high voltages. The electrically isolating thick silicon oxide layer or isolation regions can be shaped, machined, or etched to provide feedthroughs for vertical or horizontal interconnects. The feedthroughs may be coated with metal or filled with metal to provide the interconnect.

Abstract: The disclosure pertains to a compact integrated fluid control valve useful in controlling process fluids handled as part of a semiconductor processing operation. In the wetted section of the valve, process fluids enter through one or more entrance ports and exit through an annular metallic valve seat. In the valve's drive section, a sliding cylinder, including an upper horizontal member tied to a lower horizontal member, moves up and down. The lower horizontal member presses a diaphragm against the valve seat to close the valve, and moves away from the valve seat to permit fluid flow through the valve. A spring presses at the top of the upper horizontal member of the sliding cylinder, while a controlled pneumatic pressure is applied at the bottom of the upper horizontal member. The balance between the force of the spring and the force of the pneumatic pressure determines the extent to which the valve is open.

Abstract: In photomask making, the environmental sensitivity of a chemically amplified photoresist is eliminated, or at least substantially reduced, by overcoating the photoresist with a thin coating (topcoat) of a protective but transmissive material. To provide improved stability during the long time period required for direct writing of a photomask pattern, typically in the range of about 20 hours, the protective topcoat material is pH adjusted to be as neutral in pH as possible, depending on other process variable requirements. For example, a pH adjusted to be in the range from about 5 to about 8 is particularly helpful. Not only is the stability of the chemically amplified photoresist better during direct writing when the protective topcoat is pH adjusted, but a photoresist-coated substrate with pH adjusted topcoat over its surface can be stored longer prior to imaging without adverse consequences.

Abstract: We have discovered that the formation of particulate inclusions at the surface and the interior of an aluminum alloy article interferes with the performance of the article when a surface of the article is protected by an anodized coating. We have also discovered that the formation of such particulate inclusions can be controlled to a large extent by controlling the concentration of particular impurities present in the alloy used to fabricate the aluminum alloy article.

Abstract: We have discovered a method of reducing the effect of material sputtered/etched during the preheating of a substrate. One embodiment of the method pertains to preheating a substrate which includes a metal-containing layer which is to be pattern etched subsequent to preheating. The method includes exposing the substrate to a preheating plasma which produces a deposit or residue during preheating which is more easily etched than said metal-containing layer during the subsequent plasma etching of said metal-containing layer.

Abstract: One principal embodiment of the disclosure pertains to a method of optically fabricating a photomask using a direct write continuous wave laser, comprising a series of steps including: applying an organic antireflection coating over a surface of a photomask which includes a chrome-containing layer; applying a chemically-amplified DUV photoresist over the organic antireflection coating; post apply baking the DUV photoresist over a specific temperature range; exposing a surface of the DUV photoresist to the direct write continuous wave laser; and, post exposure baking the imaged DUV photoresist over a specific temperature range. The direct write continuous wave laser preferably operates at a wavelength of 244 nm or 257 nm. In an alternative embodiment, the organic antireflection coating may be applied over an inorganic antireflection coating which overlies the chrome containing layer.

Abstract: A chemical-mechanical jet etching method rapidly removes large amounts of material in wafer thinning, or produces large-scale features on a silicon wafer, gallium arsenide substrate, or similar flat semiconductor workpiece, at etch rates in the range of 10-100 microns of workpiece thickness per minute. A nozzle or array of nozzles, optionally including a dual-orifice nozzle, delivers a high-pressure jet of machining etchant fluid to the surface of the workpiece. The machining etchant comprises a liquid or gas, carrying particulate material. The liquid may be a chemical etchant, or a solvent for a chemical etchant, if desired. The areas which are not to be etched may be shielded from the jet by a patterned mask, or the jet may be directed at areas from which material is to be removed, as in wafer thinning or direct writing, depending on the size of the desired feature or etched area.

Abstract: Disclosed herein is a method of etching a trench in a silicon-containing dielectric material, in the absence of a trench etch-stop layer, where the silicon-containing dielectric material has a dielectric constant of about 4 or less. The method comprises exposing the dielectric material to a plasma generated from a source gas comprising a fluorine-containing etchant gas and an additive gas selected from the group consisting of carbon monoxide (CO), argon, and combinations thereof. A volumetric flow ratio of the additive gas to the fluorine-containing etchant gas is within the range of about 1.25:1 to about 20:1 (more typically, about 2.5:1 to about 20:1), depending on the particular fluorine-containing etchant gas used. The method provides good control over critical dimensions and etch profile during trench etching. Also disclosed herein is a method of forming a dual damascene structure, without the need for an intermediate etch stop layer.

Abstract: The present invention pertains to a method of fabricating a surface within a MEM which is free moving in response to stimulation. The free moving surface is fabricated in a series of steps which includes a release method, where release is accomplished by a plasmaless etching of a sacrificial layer material. An etch step is followed by a cleaning step in which by-products from the etch step are removed along with other contaminants which may lead to stiction. There are a series of etch and then clean steps so that a number of “cycles” of these steps are performed. Between each etch step and each clean step, the process chamber pressure is typically abruptly lowered, to create turbulence and aid in the removal of particulates which are evacuated from the structure surface and the process chamber by the pumping action during lowering of the chamber pressure. The final etch/clean cycle may be followed by a surface passivation step in which cleaned surfaces are passivated and/or coated.

Abstract: We have discovered a method which permits plasma etching at a constant etch rate. The constant etch rate is achieved by controlling plasma process parameters so that a stable plasma is obtained, with a portion of the power deposited to the plasma being a capacitive contribution, and a portion being an inductive contribution. In particular, a stable plasma may be obtained within two process regions. In the first region, the gradient of the capacitive power to the power applied to the inductively coupled source for plasma generation [∂Pcap/∂PRF] is greater than 0. In the second region, plasma stability is controlled so that [∂Pcap/∂PRF] is less than 0 and so that Pcap<<PRF. Typically, the magnitude of Pcap is less than about 10% of the magnitude of PRF. Operation of the etch process in a stable plasma region enables use of a timed etch end point.

Abstract: We have discovered a method of producing a complex-shaped aluminum alloy article, where welding has been employed to form the article, where an anodized aluminum coating is produced over a surface of the article including the weld joint, and where the anodized aluminum coating is uniform, providing improved performance over that previously known in the art for welded articles exposed to a corrosive plasma environment.

Abstract: A plasma fluorine resistant polycrystalline alumina ceramic material is produced by forming a green body including alumina and a binder, and sintering the green body for a time from about 8 to 12 hours. The area % of unsintered particles in the polycrystalline alumina ceramic material does not exceed 0.1 area %, resulting in reduced emission of particles from the material after exposure to plasma fluorine.

Abstract: We have discovered a method of detecting the approach of an endpoint during the etching of a material within a recess such as a trench or a contact via. The method provides a clear and distinct inflection endpoint signal, even for areas of a substrate containing isolated features. The method includes etching the material in the recess and using thin film interferometric endpoint detection to detect an endpoint of the etch process, where the interferometric incident light beam wavelength is tailored to the material being etched; the spot size of the substrate illuminated by the light beam is sufficient to provide adequate signal intensity from the material being etched; and the refractive index of the material being etched is sufficiently different from the refractive index of other materials contributing to reflected light from the substrate, that the combination of the light beam wavelength, the spot size, and the difference in refractive index provides a clear and distinct endpoint signal.

Abstract: Various options for improving throughput in an e-beam lithography apparatus are described. A slider lens moves in synchronism with the scanning motion of the electron beam.