A semiconductor package includes a substrate, a first semiconductor chip on the substrate, a second semiconductor chip on the first semiconductor chip and a connection structure. The second semiconductor chip includes a first segment that protrudes outwardly beyond one side of the first semiconductor chip and a second connection pad on a bottom surface of the first segment of the second semiconductor chip. The connection structure includes a first structure between the substrate and the first segment of the second semiconductor chip and a first columnar conductor penetrating the first structure to be in contact with the substrate and being disposed between the second connection pad and the substrate, thereby electrically connecting the second semiconductor chip to the substrate.

An SiC semiconductor device includes an SiC semiconductor layer including an SiC monocrystal and having a first main surface as an element forming surface, a second main surface at a side opposite to the first main surface, and a plurality of side surfaces connecting the first main surface and the second main surface, and a plurality of modified lines formed one layer each at the respective side surfaces of the SiC semiconductor layer and each extending in a band shape along a tangential direction to the first main surface of the SiC semiconductor layer and modified to be of a property differing from the SiC monocrystal.

An SiC semiconductor device includes an SiC semiconductor layer including an SiC monocrystal and having a first main surface as an element forming surface, a second main surface at a side opposite to the first main surface, and a plurality of side surfaces connecting the first main surface and the second main surface, and a plurality of modified lines formed one layer each at the respective side surfaces of the SiC semiconductor layer and each extending in a band shape along a tangential direction to the first main surface of the SiC semiconductor layer and modified to be of a property differing from the SiC monocrystal.

The present invention relates to a cooling system where a semiconductor component including a semiconductor chip and a cooling apparatus are joined, wherein a coolant is supplied to a substrate, on which a semiconductor chip is installed, through an opening member of the cooling apparatus so that a surface of the substrate may be directly cooled by the coolant so as to improve cooling efficiency, and a cooling post structure, which enables the coolant to smoothly flow, is used to further improve cooling efficiency.

The present invention relates to a cooling system where a semiconductor component including a semiconductor chip and a cooling apparatus are joined, wherein a coolant is supplied to a substrate, on which a semiconductor chip is installed, through an opening member of the cooling apparatus so that a surface of the substrate may be directly cooled by the coolant so as to improve cooling efficiency, and a cooling post structure, which enables the coolant to smoothly flow, is used to further improve cooling efficiency.

A capacitor structure and method of forming the capacitor structure is provided, including a providing a doped region of a substrate having a two-dimensional trench array with a plurality of segments defined therein. Each of the plurality of segments has an array of a plurality of recesses extending along the substrate, where the plurality of segments are rotationally symmetric about a center of the two-dimensional trench array. A first conducting layer is presented over the surface and a bottom and sidewalls of the recesses and is insulated from the substrate by a first dielectric layer. A second conducting layer is presented over the first conducting layer and is insulated by a second dielectric layer. First and second contacts respectively connect to an exposed top surface of the first conducting layer and second conducting layer. A third contact connects to the substrate within a local region to the capacitor structure.

A capacitor structure and method of forming the capacitor structure is provided, including a providing a doped region of a substrate having a two-dimensional trench array with a plurality of segments defined therein. Each of the plurality of segments has an array of a plurality of recesses extending along the substrate, where the plurality of segments are rotationally symmetric about a center of the two-dimensional trench array. A first conducting layer is presented over the surface and a bottom and sidewalls of the recesses and is insulated from the substrate by a first dielectric layer. A second conducting layer is presented over the first conducting layer and is insulated by a second dielectric layer. First and second contacts respectively connect to an exposed top surface of the first conducting layer and second conducting layer. A third contact connects to the substrate within a local region to the capacitor structure.

There is provided an electronic circuit apparatus in which the heat generated at an electronic component can be transferred to a heat spreader efficiently. An electronic circuit apparatus includes a dielectric substrate, an electronic component, a heat spreader, and a conductive via. The conductive via electrically and thermally connects the electronic component and the heat spreader. The conductive via extends from the first surface to at least an interior of the heat spreader and is in surface-contact with the heat spreader.

There is provided an electronic circuit apparatus in which the heat generated at an electronic component can be transferred to a heat spreader efficiently. An electronic circuit apparatus includes a dielectric substrate, an electronic component, a heat spreader, and a conductive via. The conductive via electrically and thermally connects the electronic component and the heat spreader. The conductive via extends from the first surface to at least an interior of the heat spreader and is in surface-contact with the heat spreader.

In described examples, a microelectronic device includes a microelectronic die with a die attach surface. The microelectronic device further includes a nanoparticle layer coupled to the die attach surface. The nanoparticle layer may be in direct contact with the die attach surface, or may be coupled to the die attach surface through an intermediate layer, such as an adhesion layer or a contact metal layer. The nanoparticle layer includes nanoparticles having adjacent nanoparticles adhered to each other. The microelectronic die is attached to a package substrate by a die attach material. The die attach material extends into the nanoparticle layer and contacts at least a portion of the nanoparticles.