Patent application number | Description | Published |
20140113433 | WAFER BONDING FOR 3D DEVICE PACKAGING FABRICATION - An apparatus and method bond a first wafer to a second wafer. The apparatus includes a first pressure application device configured to apply pressure at a central region of the first wafer in a direction toward the second wafer to initiate a bonding process between the first wafer and the second wafer. The apparatus also includes one or more second pressure application devices configured to apply pressure between the central region and an outer edge of the first wafer to complete the bonding process. The one or more second pressure application devices apply pressure on the first wafer after the first pressure application device has initiated the bonding process and while the first pressure application device continues to apply pressure at the central region. A controller controls the first pressure application device and the one or more second pressure application devices. | 04-24-2014 |
20140252502 | MULTILAYER DIELECTRIC STRUCTURES FOR SEMICONDUCTOR NANO-DEVICES - Multilayer dielectric structures are provided having silicon nitride (SiN) and silicon oxynitride (SiNO) films for use as capping layers, liners, spacer barrier layers, and etch stop layers, and other components of semiconductor nano-devices. For example, a semiconductor structure includes a multilayer dielectric structure having multiple layers of dielectric material including one or more SiN layers and one or more SiNO layers. The layers of dielectric material in the multilayer dielectric structure have a thickness in a range of about 0.5 nanometers to about 3 nanometers. | 09-11-2014 |
20140256153 | MULTILAYER DIELECTRIC STRUCTURES FOR SEMICONDUCTOR NANO-DEVICES - Multilayer dielectric structures are provided having silicon nitride (SiN) and silicon oxynitride (SiNO) films for use as capping layers, liners, spacer barrier layers, and etch stop layers, and other components of semiconductor nano-devices. For example, a semiconductor structure includes a multilayer dielectric structure having multiple layers of dielectric material including one or more SiN layers and one or more SiNO layers. The layers of dielectric material in the multilayer dielectric structure have a thickness in a range of about 0.5 nanometers to about 3 nanometers. | 09-11-2014 |
20140261960 | WAFER-TO-WAFER OXIDE FUSION BONDING - Oxide-oxide fusion bonding of wafers that includes performing a van der Waals force bonding process with a chuck having at least a flat central zone and an outer annular zone lower than the central zone, an edge portion of a mounted wafer is biased towards the outer annular zone. The van der Waals bonding wave is disrupted at the outer annular zone, causing an edge gap. A thermocompression bonding process is performed that includes heating the bonded wafers to a temperature sufficient to initiate condensation of silanol groups between the bonding surfaces, reducing the atmospheric pressure to cause degassing from between the wafers, applying a compression force to the wafers with flat chucks so as to substantially eliminate the edge gap, and performing a permanent anneal bonding process. | 09-18-2014 |
20140353828 | SUBSTRATE BONDING WITH DIFFUSION BARRIER STRUCTURES - A metallic dopant element having a greater oxygen-affinity than copper is introduced into, and/or over, surface portions of copper-based metal pads and/or surfaces of a dielectric material layer embedding the copper-based metal pads in each of two substrates to be subsequently bonded. A dopant-metal silicate layer may be formed at the interface between the two substrates to contact portions of metal pads not in contact with a surface of another metal pad, thereby functioning as an oxygen barrier layer, and optionally as an adhesion material layer. A dopant metal rich portion may be formed in peripheral portions of the metal pads in contact with the dopant-metal silicate layer. A dopant-metal oxide portion may be formed in peripheral portions of the metal pads that are not in contact with a dopant-metal silicate layer. | 12-04-2014 |
20150069608 | THROUGH-SILICON VIA STRUCTURE AND METHOD FOR IMPROVING BEOL DIELECTRIC PERFORMANCE - An improved through-silicon via (TSV) and method of fabrication are disclosed. A back-end-of-line (BEOL) stack is formed on a semiconductor substrate. A TSV cavity is formed in the BEOL stack and semiconductor substrate. A conformal protective layer is disposed on the interior surface of the TSV cavity, along the BEOL stack and partway into the semiconductor substrate. The conformal protective layer serves to protect the dielectric layers within the BEOL stack during subsequent processing, improving the integrated circuit quality and product yield. | 03-12-2015 |
20150097274 | THROUGH-SILICON VIA STRUCTURE AND METHOD FOR IMPROVING BEOL DIELECTRIC PERFORMANCE - An improved through-silicon via (TSV) is disclosed. A semiconductor substrate has a a back-end-of-line (BEOL) stack formed thereon. The BEOL stack and semiconductor substrate has a TSV cavity formed thereon. A conformal protective layer is disposed on the interior surface of the TSV cavity, along the BEOL stack and partway into the semiconductor substrate. The conformal protective layer serves to protect the dielectric layers within the BEOL stack during subsequent processing, improving the integrated circuit quality and product yield. | 04-09-2015 |
20150191824 | MICROWAVE PLASMA AND ULTRAVIOLET ASSISTED DEPOSITION APPARATUS AND METHOD FOR MATERIAL DEPOSITION USING THE SAME - A deposition apparatus for depositing a material on a substrate is provided. The deposition apparatus has a processing chamber defining a processing space in which the substrate is arranged, an ultraviolet radiation assembly configured to emit ultraviolet radiation and a microwave radiation assembly configured to emit microwave radiation into an excitation space that can be the same as the processing space, and a gas feed assembly configured to feed a precursor gas into the processing space and a reactive gas into the excitation space. The ultraviolet radiation assembly and the microwave radiation assembly are operated in combination to excite the reactive gas in the excitation space. The material is deposited on the substrate from the reaction of the excited reactive gas and the precursor gas. A method for using the deposition apparatus to deposit a material on a substrate is provided. | 07-09-2015 |