An electronic sandwich structure which has at least a first and a second part to be joined, which are sintered together by means of a sintering layer. The sintering layer is formed as a substantially uninterrupted connecting layer, the density of which varies in such a way that at least one region of higher density and at least one region of lower density alternate with one another. A method for forming a sintering layer of an electronic sandwich structure, in which firstly a sintering material layer is applied substantially continuously to a first part to be joined as a connecting layer, this sintering material layer is subsequently dried and, finally, alternating regions of higher density and of lower density of the connecting layer are produced by sintering the first part to be joined with the sintering layer on a second part to be joined.

An apparatus for enhancing the thermal performance of semiconductor packages effectively. The concept of this invention is to provide silicon nanowires on the backside of an integrated circuit die to directly attach the die to the substrate, thereby improving the interface between die and substrate, and thus enhancing thermal performance and enhancing reliability by improving adhesion.

Implementations of semiconductor packages may include: a semiconductor wafer, a glass lid fixedly coupled to a first side of the semiconductor die by an adhesive, a redistribution layer coupled to a second side of the semiconductor die, and a plurality of ball mounts coupled to the redistribution layer on a side of the redistribution layer coupled to the semiconductor die. The adhesive may be located in a trench around a perimeter of the semiconductor die and located in a corresponding trench around a perimeter of the glass lid.

Provided are: a conductive paste in which sinterability of silver particles the conductive paste can be easily controlled by using silver particles having predetermined crystal transformation characteristics defined by an XRD analysis, and after a sintering treatment, excellent electrical conductivity and thermal conductivity can be stably obtained; and a die bonding method using the conductive paste.

Disclosed is a conductive paste which includes silver particles having a volume average particle size of 0.1 to 30 m as a sinterable conductive material, and a dispersing medium for making a paste-like form, and in which when the integrated intensity of the peak at 2=380.2 in the X-ray diffraction chart obtainable by an XRD analysis before a sintering treatment of the silver particles is designated as S1, and the integrated intensity of the peak at 2=380.2 in the X-ray diffraction chart obtainable by an XRD analysis after a sintering treatment (250 C., 60 minutes) of the silver particles is designated as S2, the value of S2/S1 is adjusted to a value within the range of 0.2 to 0.8.

Provided are: a conductive paste in which sinterability of silver particles the conductive paste can be easily controlled by using silver particles having predetermined crystal transformation characteristics defined by an XRD analysis, and after a sintering treatment, excellent electrical conductivity and thermal conductivity can be stably obtained; and a die bonding method using the conductive paste.

Disclosed is a conductive paste which includes silver particles having a volume average particle size of 0.1 to 30 m as a sinterable conductive material, and a dispersing medium for making a paste-like form, and in which when the integrated intensity of the peak at 2=380.2 in the X-ray diffraction chart obtainable by an XRD analysis before a sintering treatment of the silver particles is designated as S1, and the integrated intensity of the peak at 2=380.2 in the X-ray diffraction chart obtainable by an XRD analysis after a sintering treatment (250 C., 60 minutes) of the silver particles is designated as S2, the value of S2/S1 is adjusted to a value within the range of 0.2 to 0.8.

The present disclosure, in some embodiments, relates to an integrated chip structure. The integrated chip structure includes a bump structure disposed on a first substrate and a molding compound in physical contact with the bump structure. The bump structure protrudes from the molding compound. A conductive region is on a second substrate and contacts the bump structure. A no-flow underfill (NUF) material is vertically between the molding compound and the second substrate and laterally surrounds the bump structure. The NUF material is separated from the molding compound.

The present disclosure, in some embodiments, relates to an integrated chip structure. The integrated chip structure includes a bump structure disposed on a first substrate and a molding compound in physical contact with the bump structure. The bump structure protrudes from the molding compound. A conductive region is on a second substrate and contacts the bump structure. A no-flow underfill (NUF) material is vertically between the molding compound and the second substrate and laterally surrounds the bump structure. The NUF material is separated from the molding compound.

A method for integrating heterogeneous elements with elements residing on a target wafer is described. A source die including a compound semiconductor substrate, an etch stop layer and at least one active semiconductor element is provided. The etch stop layer is between the active semiconductor element(s) and the substrate. The etch stop layer is resistant to a plasma etch for the substrate. A bonding agent is provided on a surface of the target wafer. The source die is aligned to and placed on the part of the surface of the target wafer such that the active semiconductor element(s) are between the target wafer's surface and the substrate. The bonding agent is between the source die and the surface of the target wafer. The source die is bonded to the target wafer using the bonding agent. The substrate of the source die is removed, the removal includes performing the plasma etch.

A semiconductor package includes a package substrate, an image sensor disposed on the package substrate, and a bonding layer disposed between the package substrate and the image sensor, and including a first region and a second region, the second region has a modulus of elasticity lower than that of the first region and is disposed on a periphery of the first region.

A semiconductor package includes a package substrate, an image sensor disposed on the package substrate, and a bonding layer disposed between the package substrate and the image sensor, and including a first region and a second region, the second region has a modulus of elasticity lower than that of the first region and is disposed on a periphery of the first region.