Patent application number | Description | Published |
20080200008 | BONDING INTERFACE QUALITY BY COLD CLEANING AND HOT BONDING - The invention relates to improvements in a method for molecularly bonding first and second substrates together by placing them in surface to surface contact. The improvement includes, prior to placing the substrates in contact, cleaning the surface of one or both of the substrates in a manner to provide a cleaned surface that is slightly roughened compared to a conventionally polished surface, and heating at least one or both of the substrates prior to placing the substrates in contact while retaining the heating at least until the substrates are in surface to surface contact. | 08-21-2008 |
20090023267 | METHOD OF REDUCING ROUGHNESS OF A THICK INSULATING LAYER - A method for reducing roughness of an exposed surface of an insulator layer on a substrate, by depositing an insulator layer on a substrate wherein the insulator layer includes an exposed rough surface opposite the substrate, and then smoothing the exposed rough surface of the insulator layer by exposure to a gas plasma in a chamber. The chamber contains therein a gas at a pressure of greater than 0.25 Pa but less than 30 Pa, and the gas plasma is created using a radiofrequency generator applying to the insulator layer a power density greater than 0.6 W/cm | 01-22-2009 |
20090111243 | SOI SUBSTRATES WITH A FINE BURIED INSULATING LAYER - A method of producing a semiconductor structure having a buried insulating layer having a thickness between 2 and 25 nm, by: forming at least one insulating layer on a surface of a first or second substrate, or both, wherein the surfaces are free from an insulator or presenting a native oxide layer resulting from exposure of the substrates to ambient conditions; assembling the first and second substrates; and thinning down the first substrate, in order to obtain the semiconductor structure. In this method, the insulating layer forming stage is a plasma activation based on an oxidizing or nitriding gas. | 04-30-2009 |
20090261064 | PROCESS FOR BONDING BY MOLECULAR ADHESION - The invention relates to a process for bonding by molecular adhesion of two substrates to one another during which the surfaces of the substrates are placed in close contact and bonding occurs by propagation of a bonding front between the substrates. The invention includes, prior to bonding, a step of modifying the surface state of one or both of the surfaces of the substrates so as to regulate the propagation speed of the bonding front. The surface can be modified by locally or uniformly heating or roughening the surface(s) of the substrate(s). | 10-22-2009 |
20090294072 | EQUIPMENT FOR BONDING BY MOLECULAR ADHESION - The invention relates to equipment for carrying out a process for bonding by molecular adhesion of two substrates to one another during which the surfaces of the substrates are placed in close contact and bonding occurs by propagation of a bonding front between the substrates. The invention includes, prior to bonding, a step of modifying the surface state of one or both of the surfaces of the substrates so as to regulate the propagation speed of the bonding front. The surface can be modified by locally or uniformly heating or roughening the surface(s) of the substrate(s). | 12-03-2009 |
20100015780 | TRANSFER METHOD WITH A TREATMENT OF A SURFACE TO BE BONDED - A method for minimizing or avoiding contamination of a receiving handle wafer during transfer of a thin layer from a donor wafer. This method includes providing a donor wafer and a receiving handle wafer, each having a first surface prepared for bonding and a second surface, with the donor wafer providing a layer of material to be transferred to the receiving handle wafer. Next, at least one of the first surfaces is treated to provide increased bonding energy when the first surfaces are bonded together; the surfaces are then bonded together to form an intermediate multilayer structure; and a portion of the donor wafer is removed to transfer the thin layer to the receiving handle wafer and form the semiconductor structure. This method avoids or minimizes contamination of the second surface of the receiving handle wafer by treating only the first surface of the donor wafer prior to bonding by exposure to a plasma, and by conducting any thermal treatments after plasma activation at a temperature of 300° C. to 500° C. in order to avoid diffusion of impurities into the transfer layer. | 01-21-2010 |
20100093152 | METHOD OF BONDING TWO SUBSTRATES - The invention relates to a method of forming a structure comprising a thin layer of semiconductor material transferred from a donor substrate onto a second substrate, wherein two different atomic species are co-implanted under certain conditions into the donor substrate so as to create a weakened zone delimiting the thin layer to be transferred. The two different atomic species are implanted so that their peaks have an offset of less than 200 Å in the donor substrate, and the substrates are bonded together after roughening at least one of the bonding surfaces. | 04-15-2010 |
20100148322 | COMPOSITE SUBSTRATE AND METHOD OF FABRICATING THE SAME - The invention specifically relates to methods of fabricating a composite substrate by providing a first insulating layer on a support substrate at a thickness of e | 06-17-2010 |
20100176493 | METHOD OF SPLITTING A SUBSTRATE - A process for splitting a semiconductor substrate having an identification notch on its periphery, by creating a weakened zone in the substrate by implanting atomic species into the substrate while the substrate is held in place on a portion of its periphery during the implanting; and splitting the substrate along the weakened zone by placing the held portion of the substrate in a splitting-wave initiation sector while positioning the notch for initiating a splitting wave followed by the propagation of the wave into the substrate. During splitting the notch is positioned so that it is in a quarter of the periphery of the substrate diametrically opposite the sector for initiating the splitting wave or in the quarter of the periphery of the substrate that is centered on the sector. | 07-15-2010 |
20100187649 | CHARGE RESERVOIR STRUCTURE - The present invention relates to a process for preparing semiconductor on insulator type structures that include a semiconductor layer of a donor substrate, an insulator layer and a receiver substrate. The process includes bonding of the donor substrate onto the receiver substrate, with at least one of the substrates being coated with an insulator layer, and forming at the bonding interface a so-called trapping interface of electrically active traps suitable for retaining charge carriers. The invention also relates to a semiconductor on insulator type structure that includes such a trapping interface. | 07-29-2010 |
20100190416 | Device for polishing the edge of a semiconductor substrate - Disclosed are devices and methods for chemical and mechanical polishing of the edge of a semiconductor substrate that includes a protruding residual topography in a peripheral region of the substrate resulting from a layer transfer process based on an ion implantation step, a bonding step and a detachment step, such as Smart-Cut™. To be able to remove this step-like region, exemplary devices include a polishing pad, wherein the polishing pad is arranged and configured such that its cross section in a plane perpendicular to the surface of a substrate holder is curved. The disclosure furthermore relates to a pad holder used certain exemplary devices and methods for polishing a semiconductor substrate that has a protruding residual topography. | 07-29-2010 |
20100200854 | Method for reclaiming a surface of a substrate - A method for reclaiming a surface of a substrate, wherein the surface, in particular a silicon surface, comprises a protruding residual topography, comprising at least the layer of a first material. By providing a filling material in the non-protruding areas of the surface of the substrate and the subsequent polishing, the reclaiming can be carried out such that the material consuming double-sided polishing step used in the prior art is no longer necessary. | 08-12-2010 |
20100279487 | METHOD FOR TRANSFERRING A LAYER FROM A DONOR SUBSTRATE ONTO A HANDLE SUBSTRATE - The invention relates to a method for transferring a layer from a donor substrate onto a handle substrate wherein, after detachment, the remainder of the donor substrate is reused. To get rid of undesired protruding edge regions which are due to the chamfered geometry of the substrates, the invention proposes to carry out an additional etching process before detachment occurs. | 11-04-2010 |
20100304507 | METHOD OF PRODUCING A STRUCTURE BY LAYER TRANSFER - The invention relates to a method of producing a semiconductor structure by transferring a layer of a donor substrate to a receiver substrate, with the creation of an embrittlement zone in the donor substrate to define the transfer layer, and the treatment of the surface of one of the substrates to increase the bonding strength between them, followed by the direct wafer bonding of the substrates and the detachment of the donor substrate at the embrittlement zone to form the semiconductor structure, in which the surface of the receiver substrate, except for a peripheral crown, is covered with the transferred layer. The treatment of the substrate surface is controlled so that the bonding strength between the substrates is lower in a peripheral area than in a central area. The peripheral area has a width at least equal to the that of the crown and less than 10 mm. | 12-02-2010 |
20100323496 | PROCESS FOR MANUFACTURING A COMPOSITE SUBSTRATE - The invention relates to a process for manufacturing a composite substrate comprising bonding a first substrate ( | 12-23-2010 |
20110233720 | TREATMENT FOR BONDING INTERFACE STABILIZATION - A method and/or system are provided for producing a structure comprising a thin layer of semiconductor material on a substrate. The method includes creating an area of embrittlement in the thickness of a donor substrate, bonding the donor substrate with a support substrate and detaching the donor substrate at the level of the area of embrittlement to transfer a thin layer of the donor substrate onto the support substrate. The method also includes thermal treatment of this resulting structure to stabilize the bonding interface between the thin layer and the substrate support. The invention also relates to the structures obtained by such a process. | 09-29-2011 |
20130005122 | METHOD FOR FINISHING A SUBSTRATE OF THE SEMICONDUCTOR-ON-INSULATOR TYPE - The invention relates to finishing a substrate of the semiconductor-on-insulator (SeOI) type comprising an insulator layer buried between two semiconducting material layers. The method successively comprises:
| 01-03-2013 |
20130207244 | PROCESS FOR FABRICATING A SILICON-ON-INSULATOR STRUCTURE - Embodiments of to invention relate to a process for fabricating a silicon-on-insulator structure comprising the following steps: providing a donor substrate and a support substrate, only one of the substrates being covered with an oxide layer; forming, in the donor substrate, a weak zone; plasma activating the oxide layer; bonding the donor substrate to the support substrate in a partial vacuum; implementing a bond-strengthening anneal at a temperature of 350° C. or less causing the donor substrate to cleave along the weak zone; and carrying out a heat treatment at a temperature above 900° C. A transition from the temperature of the bond-strengthening anneal to the temperature of the heat treatment may be achieved at a ramp rate above 10° C./s. | 08-15-2013 |
20130273712 | PROCESS FOR FABRICATING A SILICON-ON-INSULATOR STRUCTURE EMPLOYING TWO RAPID THERMAL ANNEALING PROCESSES, AND RELATED STRUCTURES - A method for fabricating a silicon-on-insulator structure includes forming a first oxide layer on a silicon donor substrate, forming a second oxide layer on a supporting substrate, and forming a weakened zone in the donor substrate. The donor substrate is bonded to the supporting substrate by establishing direct contact between the first oxide layer on the silicon donor substrate and the second oxide layer on the supporting substrate and establishing a direct oxide-to-oxide bond therebetween. The donor substrate is split along the weakened zone to form a silicon-on-insulator structure, and the silicon-on-insulator structure is subjected to two successive rapid thermal annealing processes at temperatures T1 and T2 respectively, wherein T1 is less than or equal to T2, T1 is between 1200° C. and 1300° C., T2 is between 1240° C. and 1300° C., and when T1 is below 1240° C., then T2 is above 1240° C. | 10-17-2013 |
20130295696 | METHOD FOR TRANSFERRING A LAYER FROM A DONOR SUBSTRATE ONTO A HANDLE SUBSTRATE - The invention relates to a method for transferring a layer from a donor substrate onto a handle substrate wherein, after detachment, the remainder of the donor substrate is reused. To get rid of undesired protruding edge regions which are due to the chamfered geometry of the substrates, the invention proposes to carry out an additional etching process before detachment occurs. | 11-07-2013 |
20130309841 | METHOD FOR MOLECULAR BONDING OF SILICON AND GLASS SUBSTRATES - The present invention concerns a method for bonding a first substrate having a first surface to a second substrate having a second surface. This method includes the steps of holding the first substrate by at least two support points, positioning the first substrate and the second substrate so that the first surface and the second surface face each other, deforming the first substrate by applying between at least one pressure point and the two support points a strain toward the second substrate, bringing the deformed first surface and the second surface into contact, and progressively releasing the strain to facilitate bonding of the substrates while minimizing or avoiding the trapping of air bubbles between the substrates. | 11-21-2013 |
20140038388 | METHOD FOR MANUFACTURING A SEMICONDUCTOR-ON-INSULATOR STRUCTURE HAVING LOW ELECTRICAL LOSSES, AND CORRESPONDING STRUCTURE - A manufacturing process for a semiconductor-on-insulator structure having reduced electrical losses and which includes a support substrate made of silicon, an oxide layer and a thin layer of semiconductor material, and a polycrystalline silicon layer interleaved between the support substrate and the oxide layer. The process includes a treatment capable of conferring high resistivity to the support substrate prior to formation of the polycrystalline silicon layer, and then conducting at least one long thermal stabilization on the structure at a temperature not exceeding 950° C. for at least 10 minutes. | 02-06-2014 |
20150031190 | PROCESS FOR THINNING THE ACTIVE SILICON LAYER OF A SUBSTRATE OF "SILICON ON INSULATOR" (SOI) TYPE - The invention relates to a process for thinning the active silicon layer of a substrate, which comprises an insulator layer between the active layer and a support, this process comprising one step of sacrificial thinning of active layer by formation of a sacrificial oxide layer by sacrificial thermal oxidation and deoxidation of the sacrificial oxide layer. The process is noteworthy in that it comprises: a step of forming a complementary oxide layer, on the active layer, using an oxidizing plasma, this layer having a thickness profile complementary to that of oxide layer, so that the sum of the thicknesses of the oxide layer and of the sacrificial silicon oxide layer are constant over the surface of the treated substrate, a step of deoxidation of this oxide layer, so as to thin active layer by a uniform thickness. | 01-29-2015 |
20150056783 | SYSTEMS AND METHODS FOR MOLECULAR BONDING OF SUBSTRATES - A method for bonding a first substrate having a first surface to a second substrate having a second surface. This method includes the steps of holding the first substrate by at least two support points, positioning the first substrate and the second substrate so that the first surface and the second surface face each other, deforming the first substrate by applying between at least one pressure point and the two support points a strain toward the second substrate, bringing the deformed first surface and the second surface into contact, and progressively releasing the strain to facilitate bonding of the substrates while minimizing or avoiding the trapping of air bubbles between the substrates. | 02-26-2015 |