A semiconductor device includes first and second chips that are stacked such that first surfaces of their element layers face each other. Each chip has a substrate, an element layer on a first surface of the substrate, pads on the element layer, and vias that penetrate through the substrate and the element layer. Each via is exposed from a second surface of the substrate and directly connected to one of the pads. The vias include a first via of the first chip directly connected to a first pad of the first chip and a second via of the second chip directly connected to a second pad of the second chip. The pads further include a third pad of the second chip which is electrically connected to the second pad by a wiring in the element layer of the second chip and to the first pad through a micro-bump.

A semiconductor package test system includes a test pack on which a semiconductor package is loaded, and a semiconductor package testing apparatus. The semiconductor package testing apparatus includes a receiving section that receives the test pack. The receiving section includes a pack receiving slot into which the test pack is inserted. The test pack includes a chuck on which the semiconductor package is fixed, a probe block disposed above the chuck, and a connection terminal. The receiving section includes a receiving terminal that is electrically connected to the connection terminal when the receiving terminal contacts the connection terminal. The probe block includes at least one needle configured to be electrically connected to the semiconductor package disposed on the chuck upon the chuck moving toward the semiconductor package. The receiving section is provided in plural.

A semiconductor memory device includes a first and second substrates; and a first and second element layers respectively provided on an upper surface of the first and the second substrates. The first and second substrates respectively include a first and second vias. The first and second element layers respectively includes a first and second pads respectively electrically coupled to the first and second vias, and respectively provided on an upper surface of the first and second element layers. The upper surface of the second element layer is arranged so as to be opposed to the upper surface of the first element layer. The first and second pads are electrically coupled and symmetrically arranged with respect to a surface where the first and second element layers are opposed to each other.

A semiconductor storage device includes first and second chips and first and second power supply electrodes. The first chip includes conductive layers arranged in a first direction, a semiconductor pillar extending in the first direction and facing the conductive layers, first contacts extending in the first direction and connected to the conductive layers, second contacts extending in the first direction and connected to a first power supply electrode, third contacts extending in the first direction, facing the second contacts in a direction crossing the first direction, and connected to the second power supply electrode, and first bonding electrodes connected to the first contacts. The second chip includes a semiconductor substrate, transistors provided on the semiconductor substrate, fourth contacts connected to the transistors, and second bonding electrodes connected to the fourth contacts. The first and second chips are bonded together so that respective first and second bonding electrodes are connected together.

Provided is a semiconductor package including an interposer. The semiconductor package includes: a package base substrate; a lower redistribution line structure disposed on the package base substrate and including a plurality of lower redistribution line patterns; at least one interposer including a plurality of first connection pillars spaced apart from each other on the lower redistribution line structure and connected respectively to portions of the plurality of lower redistribution line patterns, and a plurality of connection wiring patterns; an upper redistribution line structure including a plurality of upper redistribution line patterns connected respectively to the plurality of first connection pillars and the plurality of connection wiring patterns, on the plurality of first connection pillars and the at least one interposer; and at least two semiconductor chips adhered on the upper redistribution line structure while being spaced apart from each other.

A semiconductor device and a method for forming a semiconductor are provided. The semiconductor device includes: a first substrate, a first conductive line disposed on the first substrate, a second substrate opposite to the first substrate, a second conductive line disposed on the second substrate and adjacent to the first conductive line, and a plurality of bonding structures between the first conductive line and the second conductive line. The first conductive line includes a plurality of first segments separated from one another. The second conductive line includes a plurality of second segments separated from one another. Each of the bonding structures is connected to a respective first segment of the plurality of first segments and a respective second segment of the plurality of second segments such that the plurality of first segments, the plurality of bonding structures and the plurality of second segments are connected in series.

In a TSC structure, a first dielectric layer is formed over a first main surface of a substrate. A TSC is formed in the first dielectric layer and the substrate so that the TSC passes through the first dielectric layer and extends into the substrate. A conductive plate is formed over the first dielectric layer and electrically coupled with the TSC. A second dielectric layer is formed on an opposing second main surface of the substrate. A first via is formed in the second dielectric layer, and a first end of the first via extends into the substrate to be in contact with the TSC. A second via is formed in the second dielectric layer and a first end of the second via extends into the substrate. A metal line is formed over the second dielectric layer so as to be coupled to the first via and the second via.

A semiconductor device includes a first passivation layer over a circuit and. conductive pad over the first passivation layer, wherein the conductive pad is electrically connected to the circuit. A second passivation layer is disposed over the conductive pad and the first passivation layer, and has a first opening and a second opening. The first opening exposes an upper surface of a layer that extends underneath the conductive pad, and the second opening exposes the conductive pad. A first insulating layer is disposed over the second passivation layer and filling the first and second openings. A through substrate via extends through the insulating layer, second passivation layer, passivation layer, and substrate. A side of the through substrate via and the second passivation layer have a gap that is filled with the first insulating layer. A conductive via extends through the first insulating layer and connecting to the conductive pad.

A method for manufacturing a semiconductor package may include: forming a photoimageable dielectric layer on a substrate including a pad; forming a preliminary via hole in the photoimageable dielectric layer to expose the pad; forming a hard mask layer on the photoimageable dielectric layer and the pad; etching the photoimageable dielectric layer and the hard mask layer to form a via hole, a first hole, and a trench; forming a metal layer on the photoimageable dielectric layer connected to the pad; planarizing the metal layer to form a wiring pattern; and placing a semiconductor chip electrically connected to the wiring pattern. The first hole may be disposed on the via hole and connected thereto, and a diameter of the first hole may be larger than a diameter of the via hole.

In a method of manufacturing a semiconductor device first conductive layers are formed over a substrate. A first photoresist layer is formed over the first conductive layers. The first conductive layers are etched by using the first photoresist layer as an etching mask, to form an island pattern of the first conductive layers separated from a bus bar pattern of the first conductive layers by a ring shape groove. A connection pattern is formed to connect the island pattern and the bus bar pattern. A second photoresist layer is formed over the first conductive layers and the connection pattern. The second photoresist layer includes an opening over the island pattern. Second conductive layers are formed on the island pattern in the opening. The second photoresist layer is removed, and the connection pattern is removed, thereby forming a bump structure.