An apparatus for injecting solder material in via holes located in a top surface of a wafer is provided. The apparatus includes an injection head having a contact surface for contacting the top surface of the wafer, and at least one aperture for injecting the solder material though the injection head into the via holes. The apparatus further includes an evacuating device connected to the injection head for evacuating gas from the via holes. The injection head has a chamfer part on an edge of a contact surface contacting the top surface of the wafer.

An apparatus for injecting solder material in via holes located in a top surface of a wafer is provided. The apparatus includes an injection head having a contact surface for contacting the top surface of the wafer, and at least one aperture for injecting the solder material though the injection head into the via holes. The apparatus further includes an evacuating device connected to the injection head for evacuating gas from the via holes. The injection head has a chamfer part on an edge of a contact surface contacting the top surface of the wafer.

A semiconductor device has a first substrate. A first semiconductor component is disposed on a first surface of the first substrate. A second substrate includes a vertical interconnect structure on a first surface of the second substrate. A second semiconductor component is disposed on the first surface of the second substrate. The first semiconductor component or second semiconductor component is a semiconductor package. The first substrate is disposed over the second substrate with the first semiconductor component and second semiconductor component between the first substrate and second substrate. A first encapsulant is deposited between the first substrate and second substrate. A SiP submodule is disposed over the first substrate or second substrate opposite the encapsulant. A shielding layer is formed over the SiP submodule.

A semiconductor device has a first substrate. A first semiconductor component is disposed on a first surface of the first substrate. A second substrate includes a vertical interconnect structure on a first surface of the second substrate. A second semiconductor component is disposed on the first surface of the second substrate. The first semiconductor component or second semiconductor component is a semiconductor package. The first substrate is disposed over the second substrate with the first semiconductor component and second semiconductor component between the first substrate and second substrate. A first encapsulant is deposited between the first substrate and second substrate. A SiP submodule is disposed over the first substrate or second substrate opposite the encapsulant. A shielding layer is formed over the SiP submodule.

Described herein is a composition including copper ions, an acid, and at least one polyaminoamide including, a group of formula L1

[A-B-A′-Z].sub.n[Y—Z].sub.m  (L1)

where

B is a diacid fragment of formula L2

##STR00001##

A, A′ are amine fragments independently selected from the group consisting of formula L3a

##STR00002## and formula L3b

##STR00003##

Y is a co-monomer fragment;
Z is a coupling fragment of formula L4

##STR00004##

n is an integer of from 1 to 400; and
m is 0 or an integer of from 1 to 400.

Described herein is a composition including copper ions, an acid, and at least one polyaminoamide including, a group of formula L1

[A-B-A′-Z].sub.n[Y—Z].sub.m  (L1)

where

B is a diacid fragment of formula L2

##STR00001##

A, A′ are amine fragments independently selected from the group consisting of formula L3a

##STR00002## and formula L3b

##STR00003##

Y is a co-monomer fragment;
Z is a coupling fragment of formula L4

##STR00004##

n is an integer of from 1 to 400; and
m is 0 or an integer of from 1 to 400.

A three-dimensional (3D) integrated circuit (IC) is provided. In some embodiments, a second IC die is bonded to a first IC die. A seal-ring structure is arranged in a peripheral region of the 3D IC in the first IC die and the second IC die. The seal-ring structure extends from a first semiconductor substrate of the first IC die to a second semiconductor substrate of the second IC die. A plurality of through silicon via (TSV) coupling structures is arranged at the peripheral region of the 3D IC along an inner perimeter of the seal-ring structure closer to the 3D IC than the seal-ring structure. The plurality of TSV coupling structures respectively comprises a TSV disposed in the second semiconductor substrate and electrically coupling to the 3D IC through a stack of TSV wiring layers and inter-wire vias.

A three-dimensional (3D) integrated circuit (IC) is provided. In some embodiments, a second IC die is bonded to a first IC die. A seal-ring structure is arranged in a peripheral region of the 3D IC in the first IC die and the second IC die. The seal-ring structure extends from a first semiconductor substrate of the first IC die to a second semiconductor substrate of the second IC die. A plurality of through silicon via (TSV) coupling structures is arranged at the peripheral region of the 3D IC along an inner perimeter of the seal-ring structure closer to the 3D IC than the seal-ring structure. The plurality of TSV coupling structures respectively comprises a TSV disposed in the second semiconductor substrate and electrically coupling to the 3D IC through a stack of TSV wiring layers and inter-wire vias.

The present disclosure relates to a radio frequency (RF) device and a process for making the same. According to the process, a precursor wafer, which includes device regions, individual interfacial layers, individual p-type doped layers, and a silicon handle substrate, is firstly provided. Each individual interfacial layer is over an active layer of a corresponding device region, each individual p-type doped layer is over a corresponding individual interfacial layer, and the silicon handle substrate is over each individual p-type doped layer. Herein, each individual interfacial layer is formed of SiGe, and each individual p-type doped layer is a silicon layer doped with a p-type material that has a doped concentration greater than 1E18cm-3. Next, the silicon handle substrate is completely removed to provide an etched wafer, and each individual p-type doped layer is completely removed from the etched wafer.

A chip package includes an interposer comprising a silicon substrate, multiple metal vias passing through the silicon substrate, a first interconnection metal layer over the silicon substrate, a second interconnection metal layer over the silicon substrate, and an insulating dielectric layer over the silicon substrate and between the first and second interconnection metal layers; a field-programmable-gate-array (FPGA) integrated-circuit (IC) chip over the interposer; multiple first metal bumps between the interposer and the FPGA IC chip; a first underfill between the interposer and the FPGA IC chip, wherein the first underfill encloses the first metal bumps; a non-volatile memory (NVM) IC chip over the interposer; multiple second metal bumps between the interposer and the NVM IC chip; and a second underfill between the interposer and the NVM IC chip, wherein the second underfill encloses the second metal bumps.