According to various embodiments, a method for processing an electronic component including at least one electrically conductive contact region may include: forming a contact pad including a self-segregating composition over the at least one electrically conductive contact region to electrically contact the electronic component; forming a segregation suppression structure between the contact pad and the electronic component, wherein the segregation suppression structure includes more nucleation inducing topography features than the at least one electrically conductive contact region for perturbing a chemical segregation of the self-segregating composition by crystallographic interfaces of the contact pad defined by the nucleation inducing topography features.

An element is disclosed. The element can include a non-conductive structure having a non-conductive bonding surface, a cavity at least partially extending through a portion of a thickness of the non-conductive structure from the non-conductive bonding surface, and a conductive pad disposed in the cavity. The cavity has a bottom side and a sidewall. The conductive pad has a bonding surface and a back side opposite the bonding surface. An average size of the grains at the bonding surface is smaller than an average size of the grains adjacent the bottom side of the cavity. The conductive pad can include a crystal structure with grains oriented along a 111 crystal plane. The element can be bonded to another element to form a bonded structure. The element and the other element can be directly bonded to one another without an intervening adhesive.

An element is disclosed. The element can include a non-conductive structure having a non-conductive bonding surface, a cavity at least partially extending through a portion of a thickness of the non-conductive structure from the non-conductive bonding surface, and a conductive pad disposed in the cavity. The cavity has a bottom side and a sidewall. The conductive pad has a bonding surface and a back side opposite the bonding surface. An average size of the grains at the bonding surface is smaller than an average size of the grains adjacent the bottom side of the cavity. The conductive pad can include a crystal structure with grains oriented along a 111 crystal plane. The element can be bonded to another element to form a bonded structure. The element and the other element can be directly bonded to one another without an intervening adhesive.

In a semiconductor device, a semiconductor element includes a semiconductor substrate, a surface electrode and a protective film. The semiconductor substrate has an active region and an outer peripheral region. The surface electrode includes a base electrode disposed on a front surface of the semiconductor substrate and a connection electrode disposed on the base electrode. The protective film covers a peripheral end portion of the base electrode and an outer peripheral edge of the connection electrode. The protective film has an opening to expose the connection electrode so as to enable a solder connection. A boundary between the outer peripheral edge of the connection electrode and the protective film is located at a position corresponding to the outer peripheral region in a plan view.

A semiconductor device package includes a substrate, a silicon (Si) or silicon carbide (SiC) semiconductor die, and a metal layer on a surface of the semiconductor die. The metal layer includes a bonding surface that is attached to a surface of the substrate by a die attach material. The bonding surface includes opposing edges that extend along a perimeter of the semiconductor die, and one or more non-orthogonal corners that are configured to reduce stress at an interface between the bonding surface and the die attach material. Related devices and fabrication methods are also discussed.

A method for forming a bonded structure is disclosed. The method can include providing a first element having a first non-conductive region and a first conductive feature, providing a second element having a second non-conductive region and a second conductive feature, bonding the first non-conductive region to the second non-conductive region, and imparting mechanical stress to at least one of the first conductive feature and the second conductive feature. When bonding the first non-conductive region to the second non-conductive region, the first conductive feature and the second conductive feature are spaced apart by a gap. Imparting mechanical stress to the at least one of the first conductive feature and the second conductive feature reduces the gap between the first and second conductive features. The method can include annealing the first and second elements while imparting the mechanical stress to the at least one of the first conductive feature and the second conductive feature.

The semiconductor device includes: a semiconductor element including a body portion formed in a plate shape, a protection film provided at an outer periphery on one surface of the body portion, and a metal thin film provided adjacently to an inner side of the protection film on the one surface of the body portion; a metal member joined to a surface of the metal thin film on a side opposite to the body portion, by solder; and a mold resin sealing the semiconductor element and the metal member, wherein the surface of the metal thin film on the side opposite to the body portion has, on at least a part of an outer periphery thereof, a projection portion projecting from the surface of the metal thin film, and the solder is not provided on an outer peripheral side from a top of the projection portion.

The semiconductor device includes: a semiconductor element including a body portion formed in a plate shape, a protection film provided at an outer periphery on one surface of the body portion, and a metal thin film provided adjacently to an inner side of the protection film on the one surface of the body portion; a metal member joined to a surface of the metal thin film on a side opposite to the body portion, by solder; and a mold resin sealing the semiconductor element and the metal member, wherein the surface of the metal thin film on the side opposite to the body portion has, on at least a part of an outer periphery thereof, a projection portion projecting from the surface of the metal thin film, and the solder is not provided on an outer peripheral side from a top of the projection portion.

A semiconductor device including an integrated module formed of a first semiconductor die coupled to a second semiconductor die. Each of the first and second semiconductor dies includes a number of bond pads, which are bonded to each other to form the integrated module. Each bond pad may be divided into a number of discrete pad legs. While the overall footprint of each bond pad on the first and second semiconductor dies may be the same, the bond pads on one of the dies may have a larger number of pad legs.

A semiconductor device including an integrated module formed of a first semiconductor die coupled to a second semiconductor die. Each of the first and second semiconductor dies includes a number of bond pads, which are bonded to each other to form the integrated module. Each bond pad may be divided into a number of discrete pad legs. While the overall footprint of each bond pad on the first and second semiconductor dies may be the same, the bond pads on one of the dies may have a larger number of pad legs.