Abstract: A plug structure capable of directly coupling to a packageless bonding pad without having to go through a third conductive medium. The plug structure includes several plugs on a base substrate, such as a printed circuit board or a carrier. A solder is disposed on the plug surface in which the plug can be a cylinder or mushroom-like shape and the solder can be a film or a ball.

Abstract: An ESD protection structure having sided single crystal Si junction diode for protecting an internal circuit. The ESD protection structure is electrically coupled between an input pad and a node, and the internal circuit is electrically coupled to the node. The ESD protection structure includes at least a single crystal Si resistor, which is formed over an insulating material layer and electrically coupled between the input pad and the node. The ESD protection structure further includes at least a single crystal Si-sided junction diode, which is formed over the insulating material layer and electrically coupled between one terminal of corresponding power supply and the node.

Abstract: A method is provided for depositing aluminum thin film layers to form contacts in a semiconductor integrated circuit device. All or some of the deposition process occurs at relatively low deposition rates at a temperature which allows surface migration of the deposited aluminum atoms. Aluminum deposited under these conditions tends to fill contact vias without the formation of voids. The deposition step is periodically interrupted.

Abstract: A method is provided for forming improved quality interlevel aluminum contacts in semiconductor integrated circuits. A contact opening is formed through an insulating layer. A barrier layer is deposited over the surface of the integrated circuit. An aluminum layer is then deposited at relatively low deposition rates at a temperature which allows improved surface migration of the deposited aluminum atoms. Aluminum deposited under these conditions tends to fill contact vias without the formation of voids. The low temperature deposition step can be initiated by depositing aluminum while a wafer containing the integrated circuit device is being heated from cooler temperatures within the deposition chamber.

Abstract: Interlevel contacts in semiconductor integrated circuits are fabricated by formation of a contact opening through an insulating layer. A layer of refractory metal, or refractory metal alloy, is deposited over the surface of the integrated circuit chip. An aluminum layer is then deposited at a significantly elevated temperature, so that an aluminum/refractory metal alloy is formed at the interface between the aluminum layer and the refractory metal layer. Formation of such an alloy causes an expansion of the metal within the contact opening, thereby filling the contact opening and providing a smooth upper contour to the deposited aluminum layer.

Abstract: A semiconductor fabrication method is provided for fabricating resistors in integrated circuits. This method allows the resistors to be formed with a wider range of resistance values, in contrast to the prior art in which polysilicon is used to form the resistors. In accordance with this method, the resistors are formed from refractory metal oxides. To provide only one specific resistive characteristic, one stage of hydrogen treatment is performed on a selected part of the refractory metal oxide layer where the resistor is to be formed. Through the hydrogen treatment, the selected part of the reactory metal oxide layer is converted into a semi-conductive oxide or a conductive oxide to serve as the desired resistor. Moreover, when forming a plurality of resistors with various resistive characteristics, a number of stages of hydrogen treatment are performed successively on selected portions of the refractory metal oxide layer where the resistors to be formed in the integrated circuit are defined.

Abstract: A method is provided of forming a small geometry via or contact of a semiconductor integrated circuit, and an integrated circuit formed according to the same, is disclosed. According to a first disclosed embodiment, an opening is formed partially through an insulating layer overlying a conductive region. Sidewall spacers are formed along the sidewalls of the opening. The remaining insulating layer is etched to expose the underlying conductive region. The contact dimension of the opening is smaller than the opening which can be printed from modern photolithography techniques. According to an alternate embodiment, the opening in the insulating layer expose the underlying conductive region. A polysilicon layer is formed over the insulating layer and in the opening. The polysilicon is oxidized to form a thick oxide in the opening and is etched back to form oxidized polysilicon sidewall spacers which decrease the contact dimension of the opening.

Abstract: A method for fabricating a capacitor. A first metal layer is formed on a provided substrate. A dielectric film is formed on the first metal layer. The dielectric film can be a mono-layer structure or a multi-layer structure comprising various dielectric materials. A rapid thermal process (RTP), such as a rapid thermal annealing, or a plasma treatment is performed to enhance the quality of the dielectric film. A photolithography and etching process is performed to remove a part of the dielectric film and the first metal layer to expose a part of the inter-layer dielectric layer. The remaining first conductive layer is used as a lower electrode. A conventional interconnect process is performed on the exposed inter-layer dielectric layer and on the dielectric film. For example, a glue layer is formed on the exposed inter-layer dielectric layer and on the dielectric film. A second metal layer is formed on the glue layer.

Abstract: A method of fabricating a local interconnect uses hydrogen plasma or hydrogen thermal treatment to form a local interconnect by transforming a part of the refractory metal oxide to a conductor. The local interconnect can be used to electrically connect two electrodes in a device, or to electrically connect same electrodes of different devices.

Abstract: A method of fabricating a load resistor. The load resistor is often applied in a static random access memory. The interconnect between different conductive regions such as gate and source/drain region is formed by applying a hydrogen treatment to a refractory metal oxide layer, while the load resistors are formed by applying a hydrogen treatment with different parameters as the former one. The insulation is formed by the refractory metal oxide layer which is not to be covered.

Abstract: A method is provided of forming a small geometry via or contact of a semiconductor integrated circuit, and an integrated circuit formed according to the same, is disclosed. According to a first disclosed embodiment, an opening is formed partially through an insulating layer overlying a conductive region. Sidewall spacers are formed along the sidewalls of the opening. The remaining insulating layer is etched to expose the underlying conductive region. The contact dimension of the opening is smaller than the opening which can be printed from modern photolithography techniques. According to an alternate embodiment, the opening in the insulating layer expose the underlying conductive region. A polysilicon layer is formed over the insulating layer and in the opening. The polysilicon is oxidized to form a thick oxide in the opening and is etched back to form oxidized polysilicon sidewall spacers which decrease the contact dimension of the opening.

Abstract: A method is provided of forming a small geometry via or contact of a semiconductor integrated circuit, and an integrated circuit formed according to the same, is disclosed. According to a first disclosed embodiment, an opening is formed partially through an insulating layer overlying a conductive region. Sidewall spacers are formed along the sidewalls of the opening. The remaining insulating layer is etched to expose the underlying conductive region. The contact dimension of the opening is smaller than the opening which can be printed from modern photolithography techniques. According to an alternate embodiment, the opening in the insulating layer expose the underlying conductive region. A polysilicon layer is formed over the insulating layer and in the opening. The polysilicon is oxidized to form a thick oxide in the opening and is etched back to form oxidized polysilicon sidewall spacers which decrease the contact dimension of the opening.

Abstract: A package-free bonding pad structure on a silicon chip that includes a plurality of metal pads on the upper surface of the silicon chip and a passivation layer covering the upper surface of the silicon chip. The passivation layer has a plurality of open cavities directly above the metal pad areas for exposing a portion of each metal pad. Diameter of the open cavity gets smaller on approaching the upper surface of the passivation layer and grows bigger in the neighborhood of the metal pad area.

Abstract: A method of manufacturing embedded DRAM capable of integrating memory circuit regions and logic circuit regions together such that their top surfaces are at the same height, and hence able to maintain a high degree of planarity in integrated circuits. The method includes depositing a layer of refractory metal oxide over a high aspect ratio contact hole. Then, through the selective application of a hydrogen plasma treatment or hot hydrogen treatment, a portion of the deposited refractory metal oxide on the contact hole is transformed from non-conductive to conductive material, whereas the refractory metal oxide without a hydrogen plasma treatment or hot hydrogen treatment remains non-conductive. Therefore, a non-conductive refractory metal oxide layer can be used as a dielectric layer for a DRAM capacitor.

Abstract: A method for forming an aluminum contact through an insulating layer includes the formation of an opening. A barrier layer is formed, if necessary, over the insulating layer and in the opening. A thin refractory metal layer is then formed over the barrier layer, and aluminum deposited over the refractory metal layer. Proper selection of the refractory metal layer and aluminum deposition conditions allows the aluminum to flow into the contact and completely fill it. Preferably, the aluminum is deposited over the refractory metal layer without breaking vacuum.

Abstract: A method is provided for depositing aluminum thin film layers to form contacts in a semiconductor integrated circuit device. All or some of the deposition process occurs at relatively low deposition rates at a temperature which allows improved surface migration of the deposited aluminum atoms. Aluminum deposited under these conditions tends to fill contact vias without the formation of voids. The low temperature deposition step can be initiated by depositing aluminum while a wafer containing the integrated circuit device is being heated from cooler temperatures within the deposition chamber.

Abstract: A method is provided for forming a contact opening or via of a semiconductor integrated circuit, and an integrated circuit formed according to the same. A first metal region is formed over an underlying region. A first insulating layer is formed over the integrated circuit. A second insulating layer is then formed over the first insulating layer. A portion of the second insulating layer is etched to expose a portion of the first insulating layer wherein the exposed first insulating layer and the remaining second insulating layer form a substantially planar surface. A metal oxide layer is formed over the exposed first insulating layer and the remaining second insulating layer. A photoresist layer is formed and patterned over the metal oxide layer. The metal oxide layer is then selectively etched to form a via exposing a portion of the first insulating layer. The first insulating layer in the via is then selectively etched to expose a portion of the first metal region.

Abstract: A method is provided of forming a small geometry via or contact of a semiconductor integrated circuit, and an integrated circuit formed according to the same, is disclosed. According to a first disclosed embodiment, an opening is formed partially through an insulating layer overlying a conductive region. Sidewall spacers are formed along the sidewalls of the opening. The remaining insulating layer is etched to expose the underlying conductive region. The contact dimension of the opening is smaller than the opening which can be printed from modern photolithography techniques. According to an alternate embodiment, the opening in the insulating layer expose the underlying conductive region. A polysilicon layer is formed over the insulating layer and in the opening. The polysilicon is oxidized to form a thick oxide in the opening and is etched back to form oxidized polysilicon sidewall spacers which decrease the contact dimension of the opening.

Abstract: A method for fabrication of metal to semiconductor contacts results in sloped sidewalls in contact regions. An oxide layer is deposited and etched back to form sidewall spacers. A glass layer is then deposited and heated to reflow. After reflow, an etch back of the glass layer results is sloped sidewalls at contact openings and over steps.

Abstract: A method is provided for forming contact via in an integrated circuit. Initially, a first buffer layer is formed over an insulating layer in an integrated circuit. The first buffer layer has a different etch rate from the insulating layer. A second buffer layer is then formed over the first buffer layer, with the second buffer layer having an etch rate which is faster than the first buffer layer. An isotropic etch is performed to create an opening through the second buffer layer and a portion of the first buffer layer. Because the second buffer layer etches faster than the first buffer layer, the slant of the sideswalls of the opening can be controlled. An anisotropic etch is then performed to complete formation of the contact via.