Abstract: Through vias and conductive routing layers in semiconductor substrates and associated methods of manufacturing are disclosed herein. In one embodiment, a method for processing a semiconductor substrate includes forming an aperture in a semiconductor substrate and through a dielectric on the semiconductor substrate. The aperture has a first end open at the dielectric and a second end opposite the first end. The method can also include forming a plurality of depressions in the dielectric, and simultaneously depositing a conductive material into the aperture and at least some of the depressions.

Abstract: Microelectronic devices and methods for filling vias and forming conductive interconnects in microfeature workpieces and dies are disclosed herein. In one embodiment, a method includes providing a microfeature workpiece having a plurality of dies and at least one passage extending through the microfeature workpiece from a first side of the microfeature workpiece to an opposite second side of the microfeature workpiece. The method can further include forming a conductive plug in the passage adjacent to the first side of the microelectronic workpiece, and depositing conductive material in the passage to at least generally fill the passage from the conductive plug to the second side of the microelectronic workpiece.

Abstract: Semiconductor devices are described that have a metal interconnect extending vertically through a portion of the device to the back side of a semiconductor substrate. A top region of the metal interconnect is located vertically below a horizontal plane containing a metal routing layer. Method of fabricating the semiconductor device can include etching a via into a semiconductor substrate, filling the via with a metal material, forming a metal routing layer subsequent to filling the via, and removing a portion of a bottom of the semiconductor substrate to expose a bottom region of the metal filled via.

Abstract: An interconnect assembly includes a bond pad and an interconnect structure configured to electrically couple an electronic structure to the bond pad. The interconnect structure physically contacts areas of the bond pad that are located outside of a probe contact area that may have been damaged during testing. Insulating material covers the probe contact area and defines openings spaced apart from the probe contact area. The interconnect structure extends through the openings to contact the bond pad.

Abstract: Microelectronic devices and methods for filling vias and forming conductive interconnects in microfeature workpieces and dies are disclosed herein. In one embodiment, a method includes providing a microfeature workpiece having a plurality of dies and at least one passage extending through the microfeature workpiece from a first side of the microfeature workpiece to an opposite second side of the microfeature workpiece. The method can further include forming a conductive plug in the passage adjacent to the first side of the microelectronic workpiece, and depositing conductive material in the passage to at least generally fill the passage from the conductive plug to the second side of the microelectronic workpiece.

Abstract: An interconnect assembly includes a bond pad and an interconnect structure configured to electrically couple an electronic structure to the bond pad. The interconnect structure physically contacts areas of the bond pad that are located outside of a probe contact area that may have been damaged during testing. Insulating material covers the probe contact area and defines openings spaced apart from the probe contact area. The interconnect structure extends through the openings to contact the bond pad.

Abstract: Methods of manufacturing semiconductor devices and semiconductor devices with through-substrate vias (TSVs). One embodiment of a method of manufacturing a semiconductor device includes forming an opening through a dielectric structure and at least a portion of a semiconductor substrate, and forming a dielectric liner material having a first portion lining the opening and a second portion on an outer surface of the dielectric structure laterally outside of the opening. The method further includes removing the conductive material such that the second portion of the dielectric liner material is exposed, and forming a damascene conductive line in the second portion of the dielectric liner material that is electrically coupled to the TSV.

Abstract: Pass-through 3D interconnects and microelectronic dies and systems of stacked dies that include such interconnects to disable electrical connections are disclosed herein. In one embodiment, a system of stacked dies includes a first microelectronic die having a backside, an interconnect extending through the first die to the backside, an integrated circuit electrically coupled to the interconnect, and a first electrostatic discharge (ESD) device electrically isolated from the interconnect. A second microelectronic die has a front side coupled to the backside of the first die, a metal contact at the front side electrically coupled to the interconnect, and a second ESD device electrically coupled to the metal contact. In another embodiment, the first die further includes a substrate carrying the integrated circuit and the first ESD device, and the interconnect is positioned in the substrate to disable an electrical connection between the first ESD device and the interconnect.

Abstract: Semiconductor substrates with unitary vias and via terminals, and associated systems and methods are disclosed. A representative system in accordance with a particular embodiment includes a semiconductor substrate having an opening that includes a generally cylindrical portion with a generally smooth, uniform surface. The opening also includes a terminal portion extending transversely to the cylindrical portion and intersecting. A single, uniform, homogeneous volume of conductive material is disposed in both the cylindrical portion and the terminal portion of the opening, the conductive material forming a conductive path in the cylindrical portion and at least a portion of a conductive terminal in the terminal portion. The conductive terminal has a cross-section with generally flat walls aligned with crystal planes of the semiconductor substrate material. The conductive terminal projects away from the semiconductor substrate.

Abstract: Semiconductor devices may include a semiconductor substrate comprising at least one of transistors and capacitors may be located at an active surface of the semiconductor substrate. An imperforate dielectric material may be located on the active surface, the imperforate dielectric material covering the at least one of transistors and the capacitors. Electrically conductive material in contact openings may be electrically connected to the at least one of transistors and capacitors and extend to a back side surface of the semiconductor substrate. Laterally extending conductive elements may extend over the back side surface of the semiconductor substrate and may be electrically connected to the conductive material in the contact openings.

Abstract: Semiconductor devices are described that have a metal interconnect extending vertically through a portion of the device to the back side of a semiconductor substrate. A top region of the metal interconnect is located vertically below a horizontal plane containing a metal routing layer. Method of fabricating the semiconductor device can include etching a via into a semiconductor substrate, filling the via with a metal material, forming a metal routing layer subsequent to filling the via, and removing a portion of a bottom of the semiconductor substrate to expose a bottom region of the metal filled via.

Abstract: Semiconductor substrates with unitary vias and via terminals, and associated systems and methods are disclosed. A representative method in accordance with a particular embodiment includes forming a blind via in a semiconductor substrate, applying a protective layer to a sidewall surface of the via, and forming a terminal opening by selectively removing substrate material from an end surface of the via, while protecting from removal substrate material against which the protective coating is applied. The method can further include disposing a conductive material in both the via and the terminal opening to form an electrically conductive terminal that is unitary with conductive material in the via. Substrate material adjacent to the terminal can then be removed to expose the terminal, which can then be connected to a conductive structure external to the substrate.

Abstract: Semiconductor devices may include a semiconductor substrate comprising at least one of transistors and capacitors may be located at an active surface of the semiconductor substrate. An imperforate dielectric material may be located on the active surface, the imperforate dielectric material covering the at least one of transistors and the capacitors. Electrically conductive material in contact openings may be electrically connected to the at least one of transistors and capacitors and extend to a back side surface of the semiconductor substrate. Laterally extending conductive elements may extend over the back side surface of the semiconductor substrate and may be electrically connected to the conductive material in the contact openings.

Abstract: Methods for making semiconductor devices are disclosed herein. A method configured in accordance with a particular embodiment includes forming one or more openings in a front side of the semiconductor device and forming sacrificial plugs in the openings that partially fill the openings. The method further includes further filling the partially filled openings with a conductive material, where individual sacrificial plugs are generally between the conductive material and a substrate of the semiconductor device. The sacrificial plugs are exposed at a backside of the semiconductor device. Contact regions can be formed at the backside by removing the sacrificial plugs.

Abstract: Pass-through 3D interconnects and microelectronic dies and systems of stacked dies that include such interconnects to disable electrical connections are disclosed herein. In one embodiment, a system of stacked dies includes a first microelectronic die having a backside, an interconnect extending through the first die to the backside, an integrated circuit electrically coupled to the interconnect, and a first electrostatic discharge (ESD) device electrically isolated from the interconnect. A second microelectronic die has a front side coupled to the backside of the first die, a metal contact at the front side electrically coupled to the interconnect, and a second ESD device electrically coupled to the metal contact. In another embodiment, the first die further includes a substrate carrying the integrated circuit and the first ESD device, and the interconnect is positioned in the substrate to disable an electrical connection between the first ESD device and the interconnect.

Abstract: Microelectronic devices with through-silicon vias and associated methods of manufacturing such devices. One embodiment of a method for forming tungsten through-silicon vias comprising forming an opening having a sidewall such that the opening extends through at least a portion of a substrate on which microelectronic structures have been formed. The method can further include lining the sidewall with a dielectric material, depositing tungsten on the dielectric material such that a cavity extends through at least a portion of the tungsten, and filling the cavity with a polysilicon material.

Abstract: Methods of manufacturing semiconductor devices and semiconductor devices with through-substrate vias (TSVs). One embodiment of a method of manufacturing a semiconductor device includes forming an opening through a dielectric structure and at least a portion of a semiconductor substrate, and forming a dielectric liner material having a first portion lining the opening and a second portion on an outer surface of the dielectric structure laterally outside of the opening. The method further includes removing the conductive material such that the second portion of the dielectric liner material is exposed, and forming a damascene conductive line in the second portion of the dielectric liner material that is electrically coupled to the TSV.

Abstract: Pass-through 3D interconnects and microelectronic dies and systems of stacked dies that include such interconnects to disable electrical connections are disclosed herein. In one embodiment, a system of stacked dies includes a first microelectronic die having a backside, an interconnect extending through the first die to the backside, an integrated circuit electrically coupled to the interconnect, and a first electrostatic discharge (ESD) device electrically isolated from the interconnect. A second microelectronic die has a front side coupled to the backside of the first die, a metal contact at the front side electrically coupled to the interconnect, and a second ESD device electrically coupled to the metal contact. In another embodiment, the first die further includes a substrate carrying the integrated circuit and the first ESD device, and the interconnect is positioned in the substrate to disable an electrical connection between the first ESD device and the interconnect.

Abstract: Microelectronic devices with through-silicon vias and associated methods of manufacturing such devices. One embodiment of a method for forming tungsten through-silicon vias comprising forming an opening having a sidewall such that the opening extends through at least a portion of a substrate on which microelectronic structures have been formed. The method can further include lining the sidewall with a dielectric material, depositing tungsten on the dielectric material such that a cavity extends through at least a portion of the tungsten, and filling the cavity with a polysilicon material.

Abstract: Methods of manufacturing semiconductor devices and semiconductor devices with through-substrate vias (TSVs). One embodiment of a method of manufacturing a semiconductor device includes forming an opening through a dielectric structure and at least a portion of a semiconductor substrate, and forming a dielectric liner material having a first portion lining the opening and a second portion on an outer surface of the dielectric structure laterally outside of the opening. The method further includes removing the conductive material such that the second portion of the dielectric liner material is exposed, and forming a damascene conductive line in the second portion of the dielectric liner material that is electrically coupled to the TSV.