An embodiment of the invention may include a semiconductor structure, and method of forming the semiconductor structure. The semiconductor structure may include a first set of pillars located on a first substrate. The semiconductor structure may include a second set of pillars located on a second substrate. The semiconductor structure may include a joining layer connecting the first pillar to the second pillar. The semiconductor structure may include an underfill layer located between the first and second substrate.

Provided herein are methods and related apparatus that facilitate patterning by performing highly non-conformal (directional) deposition on patterned structures. The methods involve depositing films on a patterned structure, such as a hard mask. The deposition may be both substrate-selective such that the films have high etch selectivity with respect to an underlying material to be etched and pattern-selective such that the films are directionally deposited to replicate the pattern of the patterned structure. In some embodiments, the deposition is performed in the same chamber as a subsequent etch is performed. In some embodiments, the deposition may be performed in a separate chamber (e.g., a PECVD deposition chamber) that is connected to the etch chamber by a vacuum transfer chamber. The deposition may be performed prior to or at selected intermittences during at etch process. In some embodiments, the deposition involves multiple cycles of a deposition and treatment process.

An embodiment of the invention may include a semiconductor structure, and method of forming the semiconductor structure. The semiconductor structure may include a first set of pillars located on a first substrate. The semiconductor structure may include a second set of pillars located on a second substrate. The semiconductor structure may include a joining layer connecting the first pillar to the second pillar. The semiconductor structure may include an underfill layer located between the first and second substrate.

An embodiment of the invention may include a semiconductor structure, and method of forming the semiconductor structure. The semiconductor structure may include a first set of pillars located on a first substrate. The semiconductor structure may include a second set of pillars located on a second substrate. The semiconductor structure may include a joining layer connecting the first pillar to the second pillar. The semiconductor structure may include an underfill layer located between the first and second substrate.

An embodiment of the invention may include a semiconductor structure, and method of forming the semiconductor structure. The semiconductor structure may include a first set of pillars located on a first substrate. The semiconductor structure may include a second set of pillars located on a second substrate. The semiconductor structure may include a joining layer connecting the first pillar to the second pillar. The semiconductor structure may include an underfill layer located between the first and second substrate.

Electronic assemblies and their manufacture are described. One embodiment relates to a method including depositing an organic thin film layer on metal bumps on a semiconductor wafer, the organic thin film layer also being formed on a surface adjacent to the metal bumps on the wafer. The wafer is diced into a plurality of semiconductor die structures, the die structures including the organic thin film layer. The semiconductor die structures are attached to substrates, wherein the attaching includes forming a solder bond between the metal bumps on a die structure and bonding pads on a substrate, and wherein the solder bond extends through the organic thin film layer. The organic thin film layer is then exposed to a plasma. Other embodiments are described and claimed.

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.

An exemplary method includes forming a vertical pillar overlying or laterally displaced from a bond pad overlying a semiconductor substrate, and applying a discrete solder sphere in combination with one of a solder paste or flux on a top surface of the pillar, wherein the one of the solder paste or flux is defined by at least one photoresist layer. The method may include applying a solder sphere and/or solder flux in different combinations on top surfaces of different first and second pillars.

A system and method for conductive pillars is provided. An embodiment comprises a conductive pillar having trenches located around its outer edge. The trenches are used to channel conductive material such as solder when a conductive bump is formed onto the conductive pillar. The conductive pillar may then be electrically connected to another contact through the conductive material.

An electronic chip including a support and connection pillars, each connection pillar including a trunk including an end portion and an intermediate portion coupling the end portion to the support, and including a collar at the junction between the end portion and the intermediate portion.