An example device in accordance with an aspect of the present disclosure includes a first layer and a second layer to be bonded to the first layer. The first and second layers are materials that generate gas byproducts when bonded, and the first and/or second layers is/are compatible with photonic device operation based on a separation distance. At least one bonding interface layer is to establish the separation distance for photonic device operation, and is to prevent gas trapping and to facilitate bonding between the first layer and the second layer.

A method of forming a microelectronic device comprises forming a microelectronic device structure comprising a base structure, a doped semiconductive structure comprising a first portion overlying the base structure and second portions vertically extending from the first portion and into the base structure, a stack structure overlying the doped semiconductive structure, cell pillar structures vertically extending through the stack structure and to the doped semiconductive structure, and digit line structures vertically overlying the stack structure. An additional microelectronic device structure comprising control logic devices is formed. The microelectronic device structure is attached to the additional microelectronic device structure to form a microelectronic device structure assembly. The carrier structure and the second portions of the doped semiconductive structure are removed. The first portion of the doped semiconductive structure is then patterned to form at least one source structure coupled to the cell pillar structures. Devices and systems are also described.

A method of forming a microelectronic device comprises forming a microelectronic device structure comprising a base structure, a doped semiconductive structure comprising a first portion overlying the base structure and second portions vertically extending from the first portion and into the base structure, a stack structure overlying the doped semiconductive structure, cell pillar structures vertically extending through the stack structure and to the doped semiconductive structure, and digit line structures vertically overlying the stack structure. An additional microelectronic device structure comprising control logic devices is formed. The microelectronic device structure is attached to the additional microelectronic device structure to form a microelectronic device structure assembly. The carrier structure and the second portions of the doped semiconductive structure are removed. The first portion of the doped semiconductive structure is then patterned to form at least one source structure coupled to the cell pillar structures. Devices and systems are also described.

A method of forming a microelectronic device comprises forming a microelectronic device structure comprising a base structure, a doped semiconductive material overlying the base structure, a stack structure overlying the doped semiconductive material, cell pillar structures vertically extending through the stack structure and the doped semiconductive material and into the base structure, and digit line structures vertically overlying the stack structure. An additional microelectronic device structure comprising control logic devices is formed. The microelectronic device structure is attached to the additional microelectronic device structure to form a microelectronic device structure assembly. The base structure and portions of the cell pillar structures vertically extending into the base structure are removed to expose the doped semiconductive material. The doped semiconductive material is then patterned to form at least one source structure over the stack structure and coupled to the cell pillar structures. Microelectronic devices and electronic systems are also described.

A method of forming a microelectronic device comprises forming a microelectronic device structure comprising a base structure, a doped semiconductive material overlying the base structure, a stack structure overlying the doped semiconductive material, cell pillar structures vertically extending through the stack structure and the doped semiconductive material and into the base structure, and digit line structures vertically overlying the stack structure. An additional microelectronic device structure comprising control logic devices is formed. The microelectronic device structure is attached to the additional microelectronic device structure to form a microelectronic device structure assembly. The base structure and portions of the cell pillar structures vertically extending into the base structure are removed to expose the doped semiconductive material. The doped semiconductive material is then patterned to form at least one source structure over the stack structure and coupled to the cell pillar structures. Microelectronic devices and electronic systems are also described.

A redistribution layer for an integrated circuit is made by forming a conductive interconnection layer; forming a conductive body in electrical contract with the interconnection layer; and covering the conductive body with a first coating layer having a thickness less than 100 nm. The first coating layer is configured to provide a protection against oxidation and/or corrosion of the conductive body. To carry out an electrical test of the integrated circuit, a testing probe locally perforates the first coating layer until the conductive body is electrically contacted by the testing probe.

A temporary fixing composition is provided that is used to temporarily fix a first bonding target material and a second bonding target material to each other before the two bonding target materials are bonded to each other. The temporary fixing composition contains a first organic component having a viscosity of less than 70 mPa.Math.s at 25° C. and a boiling point of 200° C. or lower and a second organic component having a viscosity of 70 mPa.Math.s or greater at 25° C. and a boiling point of 210° C. or higher. It is preferable that, when thermogravimetry-differential thermal analysis is performed under the conditions at a temperature increase rate of 10° C./min in a nitrogen atmosphere with a sample mass of 30 mg, the 95% mass reduction temperature is lower than 300° C.

A temporary fixing composition is provided that is used to temporarily fix a first bonding target material and a second bonding target material to each other before the two bonding target materials are bonded to each other. The temporary fixing composition contains a first organic component having a viscosity of less than 70 mPa.Math.s at 25° C. and a boiling point of 200° C. or lower and a second organic component having a viscosity of 70 mPa.Math.s or greater at 25° C. and a boiling point of 210° C. or higher. It is preferable that, when thermogravimetry-differential thermal analysis is performed under the conditions at a temperature increase rate of 10° C./min in a nitrogen atmosphere with a sample mass of 30 mg, the 95% mass reduction temperature is lower than 300° C.

A method for forming a packaged electronic device includes providing a substrate having a first major surface and an opposing second major surface. The method includes attaching an electronic device to the first major surface of the substrate and providing a first conductive structure coupled to at least a first portion of the substrate. The method includes forming a dielectric layer overlying at least part of the first conductive structure. The method includes forming a conductive layer overlying the dielectric layer and connected to a second portion of the substrate. The first conductive structure, the dielectric layer, and conductive layer are configured as a capacitor structure and further configured as one or more of an enclosure structure or a stiffener structure for the packaged electronic device.

A method for forming a packaged electronic device includes providing a substrate having a first major surface and an opposing second major surface. The method includes attaching an electronic device to the first major surface of the substrate and providing a first conductive structure coupled to at least a first portion of the substrate. The method includes forming a dielectric layer overlying at least part of the first conductive structure. The method includes forming a conductive layer overlying the dielectric layer and connected to a second portion of the substrate. The first conductive structure, the dielectric layer, and conductive layer are configured as a capacitor structure and further configured as one or more of an enclosure structure or a stiffener structure for the packaged electronic device.