Abstract: A module can include a module card and first and second microelectronic elements having front surfaces facing a first surface of the module card. The module card can also have a second surface and a plurality of parallel exposed edge contacts adjacent an edge of at least one of the first and second surfaces for mating with corresponding contacts of a socket when the module is inserted in the socket. Each microelectronic element can be electrically connected to the module card. The front surface of the second microelectronic element can partially overlie a rear surface of the first microelectronic element and can be attached thereto.

Abstract: Interposers and methods of making the same are disclosed herein. In one embodiment, an interposer includes a region having first and second oppositely facing surfaces and a plurality of pores, each pore extending in a first direction from the first surface towards the second surface, wherein alumina extends along a wall of each pore; a plurality of electrically conductive connection elements extending in the first direction, consisting essentially of aluminum and being electrically isolated from one another by at least the alumina; a first conductive path provided at the first surface for connection with a first component external to the interposer; and a second conductive path provided at the second surface for connection with a second component external to the interposer, wherein the first and second conductive paths are electrically connected through at least some of the connection elements.

Abstract: A microelectronic assembly (300) or system (1500) includes at least one microelectronic package (100) having a microelectronic element (130) mounted face up above a first surface (108) of a substrate (102), one or more columns (138, 140) of contacts (132) extending in a first direction (142) along the microelectronic element front face. Columns (104A, 105B, 107A, 107B) of terminals (105 107) exposed at a second surface (110) of the substrate extend in the first direction. First terminals (105) exposed at surface (110) in a central region (112) thereof having width (152) not more than three and one-half times a minimum pitch (150) of the columns of terminals can be configured to carry address information usable to determine an addressable memory location. An axial plane of the microelectronic element can intersect the central region.

Abstract: A microelectronic unit can include a carrier structure having a front surface, a rear surface remote from the front surface, and a recess having an opening at the front surface and an inner surface located below the front surface of the carrier structure. The microelectronic unit can also include a microelectronic element having a top surface adjacent the inner surface, a bottom surface remote from the top surface, and a plurality of contacts at the top surface. The microelectronic unit can also include terminals electrically connected with the contacts of the microelectronic element. The terminals can be electrically insulated from the carrier structure. The microelectronic unit can also include a dielectric region contacting at least the bottom surface of the microelectronic element. The dielectric region can define a planar surface located coplanar with or above the front surface of the carrier structure.

Abstract: A method of making an assembly can include forming a circuit structure defining front and rear surfaces, and forming a substrate onto the rear surface. The forming of the circuit structure can include forming a first dielectric layer coupled to the carrier. The first dielectric layer can include front contacts configured for joining with contacts of one or more microelectronic elements, and first traces. The forming of the circuit structure can include forming rear conductive elements at the rear surface coupled with the front contacts through the first traces. The forming of the substrate can include forming a dielectric element directly on the rear surface. The dielectric element can have first conductive elements facing the rear conductive elements and joined thereto. The dielectric element can include second traces coupled with the first conductive elements. The forming of the substrate can include forming terminals at a surface of the substrate.

Abstract: Representative implementations of devices and techniques provide correction for a defective die in a wafer-to-wafer stack or a die stack. A correction die is coupled to a die of the stack with the defective die. The correction die electrically replaces the defective die. Optionally, a dummy die can be coupled to other die stacks of a wafer-to-wafer stack to adjust a height of the stacks.

Abstract: A component can include a substrate having a front surface and a rear surface remote therefrom, an opening extending from the rear surface towards the front surface, and a conductive via extending within the opening. The substrate can have a CTE less than 10 ppm/° C. The opening can define an inner surface between the front and rear surfaces. The conductive via can include a first metal layer overlying the inner surface and a second metal region overlying the first metal layer and electrically coupled to the first metal layer. The second metal region can have a CTE greater than a CTE of the first metal layer. The conductive via can have an effective CTE across a diameter of the conductive via that is less than 80% of the CTE of the second metal region.

Abstract: A module can include a module card and first and second microelectronic elements having front surfaces facing a first surface of the module card. The module card can also have a second surface and a plurality of parallel exposed edge contacts adjacent an edge of at least one of the first and second surfaces for mating with corresponding contacts of a socket when the module is inserted in the socket. Each microelectronic element can be electrically connected to the module card. The front surface of the second microelectronic element can partially overlie a rear surface of the first microelectronic element and can be attached thereto.

Abstract: A microelectronic package (10) can include lower and upper package faces (11, 12), lower terminals (25) at the lower package face, upper terminals (45) at the upper package face, first and second microelectronic elements (30) each having memory storage array function, and conductive interconnects (15) each electrically connecting at least one lower terminal with at least one upper terminal. The conductive interconnects (15) can include first conductive interconnects (15a) configured to carry address in formation, signal assignments of a first set (70a) of the first interconnects having (180) rotational symmetry about a theoretical rotational axis (29) with signal assignments of a second set (70b) of first interconnects.

Abstract: A microelectronic assembly may include a substrate including a rigid dielectric layer having electrically conductive elements, a microelectronic element having a plurality of contacts exposed at a face thereof, and conductive vias extending through a compliant dielectric layer overlying the rigid dielectric layer. The vias electrically connect the substrate contacts respectively to the conductive elements, and the substrate contacts are joined respectively to the contacts of the microelectronic element. The vias, compliant layer and substrate contacts are adapted to appreciably relieve stress at the substrate contacts associated with differential thermal contact and expansion of the assembly.

Abstract: Interposers and methods of making the same are disclosed herein. In one embodiment, an interposer includes a region having first and second oppositely facing surfaces and a plurality of pores, each pore extending in a first direction from the first surface towards the second surface, wherein alumina extends along a wall of each pore; a plurality of electrically conductive connection elements extending in the first direction, consisting essentially of aluminum and being electrically isolated from one another by at least the alumina; a first conductive path provided at the first surface for connection with a first component external to the interposer; and a second conductive path provided at the second surface for connection with a second component external to the interposer, wherein the first and second conductive paths are electrically connected through at least some of the connection elements.

Abstract: Methods and apparatus for forming a semiconductor device are provided which may include any number of features. One feature is a method of forming an interconnect structure that results in the interconnect structure having a top surface and portions of the side walls of the interconnect structure covered in a dissimilar material. In some embodiments, the dissimilar material can be a conductive material or a nano-alloy. The interconnect structure can be formed by removing a portion of the interconnect structure, and covering the interconnect structure with the dissimilar material. The interconnect structure can comprise a damascene structure, such as a single or dual damascene structure, or alternatively, can comprise a silicon-through via (TSV) structure.

Abstract: A microelectronic package includes a first microelectronic element comprising logic circuitry which is flip-chip mounted to a substrate, the substrate having terminals for connection with a circuit panel or other external component. A second microelectronic element overlies a rear surface of the first microelectronic element and has contacts electrically coupled with the substrate through electrically conductive interconnects extending through a region of the first microelectronic element. A heat spreader is thermally coupled with the rear surface of the substrate, either directly or through an additional element overlying the rear surface. Additional contacts of the second microelectronic element may be coupled with contacts of the substrate through electrically conductive structure disposed beyond an edge surface of the first microelectronic element.

Abstract: A dual inline memory module can include a module card having first and second opposed surfaces and a plurality of microelectronic elements each having a surface facing a surface of the module card. The module card can have a plurality of parallel edge contacts, the edge contacts including first and second contacts, the first and second contacts configured to carry command and address information and data signals corresponding to first and second memory channels, respectively, the first memory channel being independent from the second memory channel. Each microelectronic element can have memory storage array function being of type LPDDRx and being configured to sample the command and address information at least twice per clock cycle. The plurality of microelectronic elements can be configured to implement the first and second memory channels. The first and second microelectronic elements can be configured for communication via the first and second contacts, respectively.

Abstract: A method of making a microelectronic package includes forming a dielectric encapsulation layer on an in-process unit having a substrate having a first surface and a second surface remote therefrom. A microelectronic element is mounted to the first surface of the substrate, and a plurality of conductive elements exposed at the first surface, at least some of which are electrically connected to the microelectronic element. Wire bonds have bases joined to the conductive elements and end surfaces remote from the bases and define an edge surface extending away between the base and the end surface. The encapsulation layer is formed to at least partially cover the first surface and portions of the wire bonds with unencapsulated portions of the wire bonds being defined by at least one of the end surface or a portion of the edge surface that is uncovered thereby.

Abstract: Stacked microelectronic packages comprise microelectronic elements each having a contact-bearing front surface and edge surfaces extending away therefrom, and a dielectric encapsulation region contacting an edge surface. The encapsulation defines first and second major surfaces of the package and a remote surface between the major surfaces. Package contacts at the remote surface include a first set of contacts at positions closer to the first major surface than a second set of contacts, which instead are at positions closer to the second major surface. The packages are configured such that major surfaces of each package can be oriented in a nonparallel direction with the major surface of a substrate, the package contacts electrically coupled to corresponding contacts at the substrate surface. The package stacking and orientation can provide increased packing density.

Abstract: An interconnect element includes a semiconductor or insulating material layer that has a first thickness and defines a first surface; a thermally conductive layer; a plurality of conductive elements; and a dielectric coating. The thermally conductive layer includes a second thickness of at least 10 microns and defines a second surface of the interconnect element. The plurality of conductive elements extend from the first surface of the interconnect element to the second surface of the interconnect element. The dielectric coating is between at least a portion of each conductive element and the thermally conductive layer.

Abstract: Embedded vialess bridges are provided. In an implementation, discrete pieces containing numerous conduction lines or wires in a 3-dimensional bridge piece are embedded where needed in a main substrate to provide dense arrays of signal, power, and electrical ground wires below the surface of the main substrate. Vertical conductive risers to reach the surface plane of the main substrate are also included in the discrete piece, for connecting to dies on the surface of the substrate and thereby interconnecting the dies to each other through the dense array of wires in the discrete piece. The discrete piece to be embedded may have parallel planes of conductors at regular intervals within itself, and thus may present a working surface homogeneously covered with the ends of vertical conductors available to connect surface components to each other and to ground and power at many places along the embedded piece.

Abstract: A microelectronic package can include a substrate having first and second surfaces, first, second, and third microelectronic elements each having a surface facing the first surface, terminals exposed at the second surface, and leads electrically connected between contacts of each microelectronic element and the terminals. The substrate can have first, second, and third spaced-apart apertures having first, second, and third parallel axes extending in directions of the lengths of the apertures. The contacts of the first, second, and third microelectronic elements can be aligned with one of the first, second, or third apertures. The terminals can include first and second sets of first terminals configured to carry address information. The first set can be connected with the first and third microelectronic elements and not with the second microelectronic element, and the second set can be connected with the second microelectronic element and not with the first or third microelectronic elements.

Abstract: A microelectronic assembly (300) or system (1500) includes at least one microelectronic package (100) having a microelectronic element (130) mounted face up above a first surface (108) of a substrate (102), one or more columns (138, 140) of contacts (132) extending in a first direction (142) along the microelectronic element front face. Columns (104A, 105B, 107A, 107B) of terminals (105 107) exposed at a second surface (110) of the substrate extend in the first direction. First terminals (105) exposed at surface (110) in a central region (112) thereof having width (152) not more than three and one-half times a minimum pitch (150) of the columns of terminals can be configured to carry address information usable to determine an addressable memory location. An axial plane of the microelectronic element can intersect the central region.