Optoelectronic device modules having a silicon photonics transmitter die connected to a silicon interposer are described. In an example, the optoelectronic device module includes a silicon photonics transmitter die connected to a silicon interposer, and the silicon interposer is disposed between the silicon photonics transmitter die and a substrate. The silicon interposer provides an electrical interconnect between the silicon photonics transmitter die and the substrate, and reduces a likelihood that a hybrid silicon laser on the silicon photonics transmitter die will be damaged during module operation.

A method of making a secure integrated-circuit system comprises providing a first integrated circuit in a first die having a first die size and providing a second integrated circuit in a second die. The second die size is smaller than the first die size. The second die is transfer printed onto the first die and connected to the first integrated circuit, forming a compound die. The compound die is packaged. The second integrated circuit is operable to monitor the operation of the first integrated circuit and provides a monitor signal responsive to the operation of the first integrated circuit. The first integrated circuit can be constructed in an insecure facility and the second integrated circuit can be constructed in a secure facility.

A method for optical interconnection between semiconductor chips according to an embodiment include converting an electrical signal to an optical signal, transmitting the optical signal to a second substrate disposed above or below a first substrate using an optical transmitter provided on the first substrate, receiving the optical signal using an optical detector provided on the second substrate, and converting the received optical signal to an electrical signal. Accordingly, using a mid-infrared wavelength range of light that is transparent to semiconductor materials such as silicon and next-generation high-mobility materials, it is possible to enable interconnection between stacked semiconductor chips without using metal wiring. Using optical interconnection, it is possible to significantly reduce the bandwidth and power consumption, and overcome the limitations of TSV technology, and it is possible to extend the photonics technology and platform established in the existing Si Photonics, thereby reducing the cost required for design.

A semiconductor package includes an interconnect structure having a first surface and a second surface opposite to the first surface, at least one optical chip over the first surface of the interconnect structure and electrically coupled to the interconnect structure, an insulating layer contacting the second surface of the interconnect structure, and a molding compound over the first surface of the interconnect structure. The insulating layer includes a third surface facing the second surface of the interconnect structure and a fourth surface opposite to the third surface. At least an edge of the optical chip is covered by the molding compound.

A method of manufacturing a multi-layer wafer is provided. At least one stress compensating polymer layer is applied to at least one of two heterogeneous wafers. The stress compensating polymer layer is low temperature bonded to the other of the two heterogeneous wafers to form a multi-layer wafer pair. Channels are created between die on at least one of the two heterogeneous wafers. The channels are back filled with one of oxide or polymer to create a channel oxide deposition.

A quantum bit (qubit) flip chip assembly may be formed when a qubit it formed on a first chip and an optically transmissive path is formed on a second chip. The two chips may be bonded. The optically transmissive path may provide optical access to the qubit on the first chip.

Semiconductor devices having one or more vias filled with a transparent and electrically conductive material are disclosed herein. In one embodiment, a semiconductor device includes a first semiconductor die stacked over a second semiconductor die. The first semiconductor die can include at least one via that is axially aligned with a corresponding via of the second semiconductor die. The vias of the first and second semiconductor dies can be filled with a transparent and electrically conductive material that both electrically and optically couples the first and second semiconductor dies.

A semiconductor device package is provided. The semiconductor device package includes a stack of semiconductor dies over a substrate, the substrate including a plurality of electrical contacts, and an annular lower lid disposed over the substrate and surrounding the stack of semiconductor dies. The annular lower lid includes a lower surface coupled to the substrate, an upper surface coupled to an upper lid, and an outer surface in which is formed an opening. The semiconductor device assembly further includes a circuit element disposed in the opening and electrically coupled to at least a first one of the plurality of electrical contacts. The semiconductor device assembly further includes the upper lid disposed over the annular lower lid and the stack of semiconductor dies.

Semiconductor devices having optical routing layers, and associated systems and methods, are disclosed herein. In one embodiment, a method of manufacturing a semiconductor device includes forming conductive pads on a first side of a substrate and electrically coupled to conductive material of vias extending partially through the substrate. The method further includes removing material from a second side of the substrate so that the conductive material of the vias projects beyond the second side of the substrate to define projecting portions of the conductive material. The method also includes forming an optical routing layer on the second side of the substrate and at least partially around the projecting portions of the conductive material.

A semiconductor device assembly, including an interposer comprising a glass material, a semiconductor die comprising a proximity coupling on a side of the interposer, and at least one other semiconductor die comprising a proximity coupling configured for communicating signals with the proximity coupling of the semiconductor die, on an opposing side of the interposer. The assembly may optionally be configured for optical signal communication with higher level packaging. Semiconductor device packages, systems and methods of operation are also disclosed.