Abstract: Forming an electronic structure may include forming a seed layer on a substrate, and forming a mask on the seed layer. The mask may include an aperture therein exposing a portion of the seed layer, and a barrier layer may be formed on the exposed portion of the seed layer. A bump may be formed on the barrier layer, and the mask may be removed. In addition, portions of the seed layer may be selectively removed using the barrier layer as an etch mask.

Abstract: An anodic metal layer, e.g., a tantalum layer, is deposited. An anodization mask is formed, the anodization mask exposing first portions of the tantalum layer and covering second portion of the tantalum layer. The exposed first portions of the tantalum layer are anodized to form a tantalum pentoxide layer. The amount of the tantalum layer converted to the tantalum pentoxide layer is precisely controlled by the applied anodization potential. Accordingly, the thicknesses of the remaining tantalum layer and the formed tantalum pentoxide layer are precisely controlled allowing the values of passive devices, e.g., resistors and capacitors, formed with the tantalum layer and/or the tantalum pentoxide layer to be precisely set.

Abstract: Methods of forming interconnections for an electronic device including a substrate may be provided. For example, first and second patterned layers may be formed on the substrate wherein an opening in the first and second patterned layers exposes portions of the substrate, wherein the first and second patterned layers have different compositions, and wherein the first patterned layer is between the second patterned layer and the substrate. A metal layer may be formed on the second patterned layer and on portions of the substrate exposed through the opening in the first and second patterned layers. The second patterned layer and portions of the metal layer thereon may be removed while maintaining portions of the metal layer on the portions of the substrate exposed through the opening. After removing the second mask layer, solder may be provided on the metal layer.

Abstract: Methods of forming a solder structure may include providing a wafer including a plurality of die therein, and a solder wettable pad may be formed on one of the die adjacent an edge of the die. The solder wettable pad may have a length parallel to the edge of the die and a width perpendicular to the edge of the die wherein the length parallel to the edge of the die is greater than the width perpendicular to the edge of the die. A solder bump may be plated on the solder wettable pad, and the die may be separated from the wafer along the edge of the die after plating the solder bump on the solder wettable pad. Moreover, the solder bump may be reflowed on the solder wettable pad so that the solder structure extends laterally from the solder wettable pad beyond the edge of the die after separating the die from the wafer. Related structures are also discussed.

Abstract: An electronic device may include an electronic substrate, and an under bump seed metallurgy layer on the electronic substrate. A barrier layer may be provided on the under bump seed metallurgy layer so that the under bump seed metallurgy layer is between the barrier layer and the electronic substrate, and the barrier layer may include nickel and/or copper. Moreover, portions of the under bump seed metallurgy layer may be undercut relative to portions of the barrier layer. In addition, a solder layer may be provided on the barrier layer so that the barrier layer is between the solder layer and the under bump seed metallurgy layer.

Abstract: Methods of forming an electronic device may include forming an under bump seed metallurgy layer on an electronic substrate. A nickel layer may be formed on the under bump seed metallurgy layer so that the under bump seed metallurgy layer is between the nickel layer and the electronic substrate, and portions of the under bump seed metallurgy layer may be free of the nickel layer. In addition, a solder layer may be formed on the nickel layer so that the nickel layer is between the solder layer and the under bump seed metallurgy layer. In addition, a copper layer may be formed on the under bump seed metallurgy layer before forming the nickel layer with portions of the under bump seed metallurgy layer being free of the copper layer. Accordingly, the under bump seed metallurgy layer may be between the copper layer and the electronic substrate, and the copper layer may be between the under bump seed metallurgy layer and the nickel layer. Related structures are also discussed.

Abstract: An integrated circuit device may include a substrate, a conductive pad on a surface of the substrate, and a conductive line on the surface of the substrate. Moreover, the conductive line may be connected to the conductive pad, and the conductive line may be narrow relative to the conductive pad. In addition, an insulating layer may be provided on the substrate, on the conductive line, and on edge portions of the conductive pad. The insulating layer may have a hole therein exposing a central portion of the conductive pad, and a first segment of a perimeter of the hole may substantially define an arc of a circle around the central portion of the conductive pad. A second segment of the perimeter of the hole may substantially deviate from the circle around the central portion of the conductive pad, and the second segment of the perimeter of the hole may be adjacent a connection between the conductive line and the conductive pad.

Abstract: An electronic device may include first, second, and third substrates wherein the second electronic substrate is between the first and second electronic substrates. A first electrical and mechanical connection may be provided between the first and third electronic substrates, and a second electrical and mechanical connection may be provided between the second and third electronic substrates. In addition or in an alternative, an electronic device may include a printed circuit board, a first electronic substrate on the printed circuit board, a second electronic substrate on the first electronic substrate, and a third electronic substrate on the second electronic substrate. More particularly, the first electronic substrate may be between the printed circuit board and the second electronic substrate, and the second electronic substrate may be between the first and third electronic substrates.

Abstract: Forming an electronic structure may include forming a seed layer on a substrate, and forming a mask on the seed layer. The mask may include an aperture therein exposing a portion of the seed layer, and a barrier layer may be formed on the exposed portion of the seed layer. A bump may be formed on the barrier layer, and the mask may be removed. In addition, portions of the seed layer may be selectively removed using the barrier layer as an etch mask.

Abstract: Forming an electronic structure may include forming a seed layer on a substrate, and forming a mask on the seed layer. The mask may include an aperture therein exposing a portion of the seed layer, and a barrier layer may be formed on the exposed portion of the seed layer. A bump may be formed on the barrier layer, and the mask may be removed. In addition, portions of the seed layer may be selectively removed using the barrier layer as an etch mask.

Abstract: Methods of forming an electronic structure may include forming a seed layer on an electronic substrate, and forming a conductive shunt layer on portions of the seed layer wherein portions of the seed layer are free of the conductive shunt layer. A conductive barrier layer may be formed on the conductive shunt layer opposite the seed layer wherein the conductive shunt layer comprises a first material and wherein the barrier layer comprises a second material different than the first material. Moreover, a solder layer may be formed on the barrier layer opposite the conductive shunt layer wherein the solder layer comprises a third material different than the first and second materials. Related structures are also discussed.

Abstract: Methods of forming an electronic structure may include forming a seed layer on an electronic substrate, and forming a conductive shunt layer on portions of the seed layer wherein portions of the seed layer are free of the conductive shunt layer. A conductive barrier layer may be formed on the conductive shunt layer opposite the seed layer wherein the conductive shunt layer comprises a first material and wherein the barrier layer comprises a second material different than the first material. Moreover, a solder layer may be formed on the barrier layer opposite the conductive shunt layer wherein the solder layer comprises a third material different than the first and second materials. Related structures are also discussed.

Abstract: Methods of forming interconnections for an electronic device including a substrate may be provided. For example, first and second patterned layers may be formed on the substrate wherein an opening in the first and second patterned layers exposes portions of the substrate, wherein the first and second patterned layers have different compositions, and wherein the first patterned layer is between the second patterned layer and the substrate. A metal layer may be formed on the second patterned layer and on portions of the substrate exposed through the opening in the first and second patterned layers. The second patterned layer and portions of the metal layer thereon may be removed while maintaining portions of the metal layer on the portions of the substrate exposed through the opening. After removing the second mask layer, solder may be provided on the metal layer.

Abstract: An electronic device may include a substrate with an input/output pad thereon, and a compliant dielectric layer on a first portion of the substrate such that a second portion of the substrate is free of the compliant dielectric layer. A conductive redistribution line may extend from the input/output pad to the compliant dielectric layer so that the compliant dielectric layer is between a bump pad portion of the conductive redistribution line and the substrate. A first solder bump may be on the bump pad portion of the conductive redistribution line so that the compliant dielectric layer is between the first solder bump and the substrate. A second solder bump may be on the second portion of the substrate that is free of the compliant dielectric layer. Related methods are also discussed.

Abstract: A method of processing a wafer including a plurality of integrated circuit devices on a front side of the wafer, may include thinning the wafer from a back side opposite the front side. After thinning the wafer, a back side layer may be provided on the back side of the thinned wafer opposite the front side, and the back side layer may be configured to counter stress on the front side of the wafer including the plurality of integrated circuit devices thereon. After providing the back side layer, the plurality of integrated circuit devices may be separated. Related structures are also discussed.

Abstract: A liquid prime mover can be used to position a component on a substrate. For example, a liquid material can be provided on the substrate adjacent the component such that the component has a first position relative to the substrate. A property of the liquid material can then be changed to move the component from the first position relative to the substrate to a second position relative to the substrate. Related structures are also discussed.

Abstract: A liquid prime mover can be used to position a component on a substrate. For example, a liquid material can be provided on the substrate adjacent the component such that the component has a first position relative to the substrate. A property of the liquid material can then be changed to move the component from the first position relative to the substrate to a second position relative to the substrate. Related structures are also discussed.

Abstract: Methods of bonding two components may include positioning the components relative to one another to obtain a desired orientation. Once the desired orientation is obtained, the components can be bonded in the desired orientation with metal wherein a temperature of both components is maintained below a melting temperature of the metal while bonding. Related structures are also discussed.

Abstract: Methods of bonding two components may include positioning the components relative to one another to obtain a desired orientation. Once the desired orientation is obtained, the components can be bonded in the desired orientation with metal wherein a temperature of both components is maintained below a melting temperature of the metal while bonding. Related structures are also discussed.

Abstract: Methods of forming metal-insulator-metal structures may include providing a first conductive electrode on a substrate, forming a dielectric layer on the first conductive electrode, and forming a second conductive electrode on the dielectric layer so that the dielectric layer is between the first and second conductive electrodes. In addition, a conductive layer may be formed between the dielectric layer and one of the first and second conductive electrodes wherein the conductive layer includes a conductive material that decomposes into a non-conductive material once a threshold temperature has been exceeded. Related structures are also discussed.