Abstract: Wafer processing techniques, or methods for forming semiconductor rides, are disclosed for fabricating plated pillar dies having die-level electromagnetic interference (EMI) shield layers. In embodiments, the method includes depositing a metallic seed layer over a semiconductor wafer and contacting die pads thereon. An electroplating process is then performed to compile plated pillars on the metallic seed layer and across the semiconductor wafer. Following electroplating, selected regions of the metallic seed layer are removed to produce electrical isolation gaps around a first pillar type, while leaving intact portions of the metallic seed layer to yield a wafer-level EMI shield layer. The semiconductor wafer is separated into singulated plated pillar dies, each including a die-level EMI shield layer and plated pillars of the first pillar type electrically isolated from the EMI shield layer.

Abstract: Wafer processing techniques, or methods for forming semiconductor rides, are disclosed for fabricating plated pillar dies having die-level electromagnetic interference (EMI) shield layers. In embodiments, the method includes depositing a metallic seed layer over a semiconductor wafer and contacting die pads thereon. An electroplating process is then performed to compile plated pillars on the metallic seed layer and across the semiconductor wafer. Following electroplating, selected regions of the metallic seed layer are removed to produce electrical isolation gaps around a first pillar type, while leaving intact portions of the metallic seed layer to yield a wafer-level EMI shield layer. The semiconductor wafer is separated into singulated plated pillar dies, each including a die-level EMI shield layer and plated pillars of the first pillar type electrically isolated from the EMI shield layer.

Abstract: A method of making a semiconductor device with an air gap for a terminal of a semiconductor device includes forming a sacrificial sidewall spacer and removing the spacer after the formation of contact structures for the semiconductor device. The air gap is located in portions of the wafer where the sacrificial air gap was removed. Since the contacts are formed prior to the removal of the sacrificial spacers, air gaps can advantageously be formed without electrically conductive contact material undesirably being deposited in locations of the desired air gap.

Abstract: A method of making a semiconductor device with an air gap for a terminal of a semiconductor device includes forming a sacrificial sidewall spacer and removing the spacer after the formation of contact structures for the semiconductor device. The air gap is located in portions of the wafer where the sacrificial air gap was removed. Since the contacts are formed prior to the removal of the sacrificial spacers, air gaps can advantageously be formed without electrically conductive contact material undesirably being deposited in locations of the desired air gap.

Abstract: A multigate transistor is formed on a wafer with a first material and a second material. Portions of the second material are selectively removed from the first material to form an opening in the first material. An epitaxially grown semiconductor material is grown from a seed layer into the opening. A portion of the first material is removed around the epitaxially grown semiconductor material in the opening and a gate material is formed in locations of the removed first material. The epitaxially grown semiconductor material in the opening serves as a channel region for a multigate transistor and the gate material serves as a gate for the multigate transistor.

Abstract: A multigate transistor is formed on a wafer with a first material and a second material. Portions of the second material are selectively removed from the first material to form an opening in the first material. An epitaxially grown semiconductor material is grown from a seed layer into the opening. A portion of the first material is removed around the epitaxially grown semiconductor material in the opening and a gate material is formed in locations of the removed first material. The epitaxially grown semiconductor material in the opening serves as a channel region for a multigate transistor and the gate material serves as a gate for the multigate transistor.

Abstract: In some embodiments, a substrate contact is formed by forming a first gate structure and a second gate structure. The first gate structure is formed in a first volume in a first area of the wafer and the second gate structure is formed in a second volume in a second area of the wafer. The gate dielectric is removed from the wafer in a first area of the wafer but remains in the second area. A first sidewall spacer formed for the gate structure and a second sidewall spacer is formed for the second gate structure. In some embodiments, the first gate structure can be utilized as a substrate contact and the second gate structure can be utilized as a gate of a transistor. In other embodiments, the first gate structure and the second gate structure can be removed and a metal gate material can be deposited in opening for forming a substrate contact and a metal gate, respectively.