A method of fabricating an interconnect structure includes providing a semiconductor structure and performing a first spin resist and bake cycle. The first spin resist and bake cycle includes applying a first predetermined amount of a resist material over one or more portions of the semiconductor structure and baking the semiconductor structure to form a first resist layer portion of a resist layer. The method also includes performing a next spin resist and bake cycle. The next spin resist and bake cycle includes applying a next predetermined amount of the resist material and baking the semiconductor structure to form a next resist layer portion of the resist layer. The method additionally includes depositing a conductive material in an opening formed in the resist layer and forming a conductive structure from the conductive material. An interconnect structure is also provided.

A method of fabricating an interconnect structure includes providing a semiconductor structure and performing a first spin resist and bake cycle. The first spin resist and bake cycle includes applying a first predetermined amount of a resist material over one or more portions of the semiconductor structure and baking the semiconductor structure to form a first resist layer portion of a resist layer. The method also includes performing a next spin resist and bake cycle. The next spin resist and bake cycle includes applying a next predetermined amount of the resist material and baking the semiconductor structure to form a next resist layer portion of the resist layer. The method additionally includes depositing a conductive material in an opening formed in the resist layer and forming a conductive structure from the conductive material. An interconnect structure is also provided.

A dual bond pad structure for a wafer with laser die attachment and methods of manufacture are disclosed. The method includes forming a bonding layer on a surface of a substrate. The method further includes forming solder bumps on the bonding layer. The method further includes patterning the bonding layer to form bonding pads some of which comprise the solder bumps thereon. The method further includes attaching a laser diode to selected bonding pads using solder connections formed on the laser diode. The method further includes attaching an interposer substrate to the solder bumps formed on the bonding pads.

A dual bond pad structure for a wafer with laser die attachment and methods of manufacture are disclosed. The method includes forming a bonding layer on a surface of a substrate. The method further includes forming solder bumps on the bonding layer. The method further includes patterning the bonding layer to form bonding pads some of which comprise the solder bumps thereon. The method further includes attaching a laser diode to selected bonding pads using solder connections formed on the laser diode. The method further includes attaching an interposer substrate to the solder bumps formed on the bonding pads.

A dual bond pad structure for a wafer with laser die attachment and methods of manufacture are disclosed. The method includes forming a bonding layer on a surface of a substrate. The method further includes forming solder bumps on the bonding layer. The method further includes patterning the bonding layer to form bonding pads some of which comprise the solder bumps thereon. The method further includes attaching a laser diode to selected bonding pads using solder connections formed on the laser diode. The method further includes attaching an interposer substrate to the solder bumps formed on the bonding pads.

A dual bond pad structure for a wafer with laser die attachment and methods of manufacture are disclosed. The method includes forming a bonding layer on a surface of a substrate. The method further includes forming solder bumps on the bonding layer. The method further includes patterning the bonding layer to form bonding pads some of which comprise the solder bumps thereon. The method further includes attaching a laser diode to selected bonding pads using solder connections formed on the laser diode. The method further includes attaching an interposer substrate to the solder bumps formed on the bonding pads.

A semiconductor die includes a semiconductor circuit disposed within or over a substrate. A conductive contact pad is disposed over the substrate outside the semiconductor circuit. A floating electrical path ends at a singulated edge of the die. The electrical path is electrically coupled to the conductive contact pad.

According to various embodiments, a method may include: forming a first layer on a surface using a first lift-off process; forming a second layer over the first layer using a second lift-off process; wherein the second lift-off process is configured such that the second layer covers at least one sidewall of the first layer at least partially.

An integrated circuit including a self-aligned under bump metal pad formed on a top metal interconnect level in a connection opening in a dielectric layer, with a solder ball formed on the self-aligned under bump metal pad. Processes of forming integrated circuits including a self-aligned under bump metal pad formed on a top metal interconnect level in a connection opening in a dielectric layer, by a process of forming one or more metal layers on the interconnect level and the dielectric layer, selectively removing the metal from over the dielectric layer, and subsequently forming a solder ball on the self-aligned under bump metal pad. Some examples include additional metal layers formed after the selective removal process, and may include an additional selective removal process on the additional metal layers.

Semiconductor devices comprising a getter material are described. The getter material can be located in or over the active region of the device and/or in or over a termination region of the device. The getter material can be a conductive or an insulating material. The getter material can be present as a continuous or discontinuous film. The device can be a SiC semiconductor device such as a SiC vertical MOSFET. Methods of making the devices are also described. Semiconductor devices and methods of making the same comprising source ohmic contacts formed using a self-aligned process are also described. The source ohmic contacts can comprise titanium silicide and/or titanium silicide carbide and can act as a getter material.