Abstract: A technique for forming a film of material (12) from a donor substrate (10). The technique has a step of introducing energetic particles (22) through a surface of a donor substrate (10) to a selected depth (20) underneath the surface, where the particles have a relatively high concentration to define a donor substrate material (12) above the selected depth. An energy source is directed to a selected region of the donor substrate to initiate a controlled cleaving action of the substrate (10) at the selected depth (20), whereupon the cleaving action provides an expanding cleave front to free the donor material from a remaining portion of the donor substrate.

Abstract: An apparatus and method for controlled cleaving is presented. Embodiments of the present invention include an apparatus for cleaving a substrate comprising a bottom shell coupled to a hinge mechanism, a top shell coupled to the hinge mechanism, a plurality of o-rings or suction cups coupled to the top and bottom shells for providing a suction force sufficient to exert a tensile force to the top and bottom of a substrate, a compliant member for sealing a portion of a grove edge of a substrate and for maintaining a pressure inside a volume formed between the groove edge and the groove edge of the substrate, a gas port for supplying gas to the volume, and a height adjustment mechanism coupled to the top shell and the bottom shell for separating the top shell from the bottom shell.

Abstract: A method for chemically bonding semiconductor wafers and other materials to one another without exposing wafers to wet environments, and a bonding chamber for in situ plasma bonding are disclosed. The in situ plasma bonding chamber allows plasma activation and bonding to occur without disruption of the vacuum level. This precludes rinsing of the surfaces after placement in the chamber, but allows for variations in ultimate pressure, plasma gas species, and backfill gases. The resulting bonded materials are free from macroscopic and microscopic voids. The initial bond is much stronger than conventional bonding techniques, thereby allowing for rougher materials to be bonded to one another. This bonded materials can be used for bond and etchback silicon on insulator, high voltage and current devices, radiation resistant devices, micromachined sensors and actuators, and hybrid semiconductor applications. This technique is not limited to semiconductors.

Abstract: A method of manufacturing an integrated circuit on semiconductor substrates. The method includes providing a semiconductor substrate characterized by a first lattice with a first structure and a first spacing. The semiconductor substrate has an overlying film of material with a second lattice with a second structure and a second spacing. Preferably, the second spacing placing the film of material in either a tensile or compressive mode across the entirety of the film of material relative to the semiconductor substrate with the first structure and the first spacing. The method includes processing the film of material to form a first region and a second region within the film of material. The first region and the second region are characterized by either the tensile or compressive mode. Preferably, both the first and second regions in their entirety are characterized by either the tensile or compressive mode.

Abstract: A technique for forming a gettering layer in a wafer made using a controlled cleaving process. The gettering layer can be made by implanting using beam line or plasma immersion ion implantaion, or made by forming a film of material such as polysilicon by way of chemical vapor deposition. A controlled cleaving process is used to form the wafer, which is a multilayered silicon on insulator substrate. The gettering layer removes and/or attracts impurities in the wafer, which can be detrimental to the functionality and reliability of an integrated circuit device made on the wafer.

Abstract: A method for treating a film of material, which can be defined on a substrate, e.g., silicon. The method includes providing a substrate comprising a cleaved surface, which had a porous silicon layer thereon. The substrate may have a distribution of hydrogen bearing particles defined from the cleaved surface to a region underlying said cleaved surface. The method also includes increasing a temperature of the cleaved surface to greater than about 1,000 Degrees Celsius while maintaining the cleaved surface in a etchant bearing environment to reduce a surface roughness value by about fifty percent and greater. Preferably, the value can be reduced by about eighty or ninety percent and greater, depending upon the embodiment.

Abstract: A technique for forming a film of material (12) from a donor substrate (10). The technique has a step of forming a stressed region in a selected manner at a selected depth (20) underneath the surface. An energy source such as pressurized fluid is directed to a selected region of the donor substrate to initiate a controlled cleaving action of the substrate (10) at the selected depth (20), whereupon the cleaving action provides an expanding cleave front to free the donor material from a remaining portion of the donor substrate.

Abstract: A technique for forming a film of material (12) from a donor substrate (10). The technique has a step of forming a stressed region in a selected manner at a selected depth (20) underneath the surface. An energy source such as pressurized fluid is directed to a selected region of the donor substrate to initiate a controlled cleaving action of the substrate (10) at the selected depth (20), whereupon the cleaving action provides an expanding cleave front to free the donor material from a remaining portion of the donor substrate.

Abstract: A method and technique for achieving a high strength bond between two substrates includes igniting a plasma using a source RF signal. The substrates are biased with a bias RF signal during surface treatment by the plasma. The treated surfaces are brought into contact. The resulting bonded substrates show an improvement over bonds attained using conventional bonding techniques.

Abstract: A method for chemically bonding semiconductor wafers and other materials to one another without exposing wafers to wet environments, and a bonding chamber for in situ plasma bonding are disclosed. The in situ plasma bonding chamber allows plasma activation and bonding to occur without disruption of the vacuum level. This precludes rinsing of the surfaces after placement in the chamber, but allows for variations in ultimate pressure, plasma gas species, and backfill gases. The resulting bonded materials are free from macroscopic and microscopic voids. The initial bond is much stronger than conventional bonding techniques, thereby allowing for rougher materials to be bonded to one another. This bonded materials can be used for bond and etchback silicon on insulator, high voltage and current devices, radiation resistant devices, micromachined sensors and actuators, and hybrid semiconductor applications. This technique is not limited to semiconductors.

Abstract: A technique for forming a gettering layer in a wafer made using a controlled cleaving process. The gettering layer can be made by implanting using beam line or plasma immersion ion implantaion, or made by forming a film of material such as polysilicon by way of chemical vapor deposition. A controlled cleaving process is used to form the wafer, which is a multilayered silicon on insulator substrate. The gettering layer removes and/or attracts impurities in the wafer, which can be detrimental to the functionality and reliability of an integrated circuit device made on the wafer.

Abstract: A method for chemically bonding semiconductor wafers and other materials to one another without exposing wafers to wet environments, and a bonding chamber for in situ plasma bonding are disclosed. The in situ plasma bonding chamber allows plasma activation and bonding to occur without disruption of the vacuum level. This precludes rinsing of the surfaces after placement in the chamber, but allows for variations in ultimate pressure, plasma gas species, and backfill gases. The resulting bonded materials are free from macroscopic and microscopic voids. The initial bond is much stronger than conventional bonding techniques, thereby allowing for rougher materials to be bonded to one another. These bonded materials can be used for bond and etchback silicon on insulator, high voltage and current devices, radiation resistant devices, micromachined sensors and actuators, and hybrid semiconductor applications. This technique is not limited to semiconductors.

Abstract: A technique for forming a film of material (12) from a donor substrate (10). The technique has a step of introducing energetic particles (22) through a surface of a donor substrate (10) to a selected depth (20) underneath the surface, where the particles have a relatively high concentration to define a donor substrate material (12) above the selected depth. An energy source is directed to a selected region of the donor substrate to initiate a controlled cleaving action of the substrate (10) at the selected depth (20), whereupon the cleaving action provides an expanding cleave front to free the donor material from a remaining portion of the donor substrate.

Abstract: A plasma system for processing large area substrates. In one embodiment the system includes a plurality of radiofrequency (rf) plasma sources removably attached to the rf transparent windows of a processing chamber. The number and distribution of sources is varied to provide the size and uniformity of the plasma field required to treat the substrate. A plurality of plasma probes, such as Langmuir probes, Faraday cups and optical sensor are positioned within the chamber and in electrical communication with the plasma sources adjust the rf field produced by the individual sources to maintain the desired degree of field uniformity.

Abstract: A method of forming substrates, e.g., silicon on insulator, silicon on silicon. The method includes providing a donor substrate, e.g., silicon wafer. The method also includes forming a cleave layer on the donor substrate that contains the cleave plane, the plane of eventual separation. In a specific embodiment, the cleave layer comprising silicon germanium. The method also includes forming a device layer (e.g., epitaxial silicon) on the cleave layer. The method also includes introducing particles into the cleave layer to add stress in the cleave layer. The particles within the cleave layer are then redistributed to form a high concentration region of the particles in the vicinity of the cleave plane, where the redistribution of the particles is carried out in a manner substantially free from microbubble or microcavity formation of the particles in the cleave plane. That is, the particles are generally at a low dose, which is defined herein as a lack of microbubble or microcavity formation in the cleave plane.

Abstract: A technique for forming a film of material (12) from a donor substrate (10). The technique has a step of introducing energetic particles (22) in a selected manner through a surface of a donor substrate (10) to a selected depth (20) underneath the surface, where the particles have a relatively high concentration to define a donor substrate material (12) above the selected depth and the particles for a pattern at the selected depth. An energy source such as pressurized fluid is directed to a selected region of the donor substrate to initiate a controlled cleaving action of the substrate (10) at the selected depth (20), whereupon the cleaving action provides an expanding cleave front to free the donor material from a remaining portion of the donor substrate.

Abstract: A technique for forming a film of material (12) from a donor substrate (10). The technique has a step of forming a stressed region in a selected manner at a selected depth (20) underneath the surface. An energy source such as pressurized fluid is directed to a selected region of the donor substrate to initiate a controlled cleaving action of the substrate (10) at the selected depth (20), whereupon the cleaving action provides an expanding cleave front to free the donor material from a remaining portion of the donor substrate.

Abstract: A method of smoothing a silicon surface formed on a substrate. According to the present invention a substrate having a silicon surface is placed into a chamber and heated to a temperature of between 1000°-1300° C. While the substrate is heated to a temperature between 1000°-1300° C., the silicon surface is exposed to a gas mix comprising H2 and HCl in the chamber to smooth the silicon surface.

Abstract: A hybrid silicon-on-silicon substrate. A thin film (2101) of single-crystal silicon is bonded to a target wafer (46). A high-quality bond is formed between the thin film and the target wafer during a high-temperature annealing process. It is believed that the high-temperature annealing process forms covalent bonds between the layers at the interface (2305). The resulting hybrid wafer is suitable for use in integrated circuit manufacturing processes, similar to wafers with an epitaxial layer.

Abstract: A cleaving tool provides pressurized gas to the edge of a substrate to cleave the substrate at a selected interface. A substrate, such as a bonded substrate, is loaded into the cleaving tool, and two halves of the tool are brought together to apply a selected pressure to the substrate. A compliant pad of selected elastic resistance provides support to the substrate while allowing the substrate to expand during the cleaving process. Bringing the two halves of the tool together also compresses an edge seal against the perimeter of the substrate. A thin tube connected to a high-pressure gas source extends through the edge seal and provides a burst of gas to separate the substrate into at least two sheets. In a further embodiment, the perimeter of the substrate is struck with an edge prior to applying the gas pressure.