Abstract: A chip crack detection structure, including a substrate, a first chip crack detection ring, a second chip crack detection ring, and a seal ring, is provided. The first chip crack detection ring includes multiple first conductive layers stacked over the substrate and electrically connected to each other. A bottom surface of a lowermost conductive layer among the first conductive layers is not in contact with any plug. The second chip crack detection ring surrounds the first chip crack detection ring. The second chip crack detection ring includes multiple second conductive layers stacked over the substrate and electrically connected to each other. A bottom surface of a lowermost conductive layer among the second conductive layers is not in contact with any plug. The seal ring surrounds the second chip crack detection ring. The seal ring includes multiple third conductive layers stacked over the substrate and electrically connected to each other.

Abstract: A chip crack detection structure, including a substrate, a first chip crack detection ring, a second chip crack detection ring, and a seal ring, is provided. The first chip crack detection ring includes multiple first conductive layers stacked over the substrate and electrically connected to each other. A bottom surface of a lowermost conductive layer among the first conductive layers is not in contact with any plug. The second chip crack detection ring surrounds the first chip crack detection ring. The second chip crack detection ring includes multiple second conductive layers stacked over the substrate and electrically connected to each other. A bottom surface of a lowermost conductive layer among the second conductive layers is not in contact with any plug. The seal ring surrounds the second chip crack detection ring. The seal ring includes multiple third conductive layers stacked over the substrate and electrically connected to each other.

Abstract: A method for fabricating a semiconductor device is disclosed. A semiconductor substrate comprising a MOS transistor is provided. A MEMS device is formed over the MOS transistor. The MEMS device includes a bottom electrode in a second topmost metal layer, a diaphragm in a pad metal layer, and a cavity between the bottom electrode and the diaphragm.

Abstract: A method for fabricating a semiconductor device is disclosed. A semiconductor substrate comprising a MOS transistor is provided. A MEMS device is formed over the MOS transistor. The MEMS device includes a bottom electrode in a second topmost metal layer, a diaphragm in a pad metal layer, and a cavity between the bottom electrode and the diaphragm.

Abstract: A semiconductor device includes a semiconductor substrate comprising a MOS transistor. A MEMS device is integrally constructed above the MOS transistor. The MEMS device includes a bottom electrode in a second topmost metal layer, a diaphragm in a pad metal layer, and a cavity between the bottom electrode and the diaphragm.

Abstract: A semiconductor chip is provided. The semiconductor chip includes at least one interlayer dielectric layer, a transmission pattern and a stress absorption structure. The at least one interlayer dielectric layer is disposed on a substrate. The transmission pattern is disposed on the at least one interlayer dielectric layer and within a peripheral region of the semiconductor chip. The transmission pattern is electrically connected to an external signal source. The stress absorption structure is disposed in the at least one interlayer dielectric layer within the peripheral region, and electrically connected to the transmission pattern. The stress absorption structure is covered by the transmission pattern.

Abstract: A semiconductor chip is provided. The semiconductor chip includes at least one interlayer dielectric layer, a transmission pattern and a stress absorption structure. The at least one interlayer dielectric layer is disposed on a substrate. The transmission pattern is disposed on the at least one interlayer dielectric layer and within a peripheral region of the semiconductor chip. The transmission pattern is electrically connected to an external signal source. The stress absorption structure is disposed in the at least one interlayer dielectric layer within the peripheral region, and electrically connected to the transmission pattern. The stress absorption structure is covered by the transmission pattern.

Abstract: A semiconductor device includes a semiconductor substrate comprising a MOS transistor. A MEMS device is integrally constructed above the MOS transistor. The MEMS device includes a bottom electrode in a second topmost metal layer, a diaphragm in a pad metal layer, and a cavity between the bottom electrode and the diaphragm.

Abstract: The present invention discloses a method for forming a self-aligned contact. In the present invention, a amorphous SiC layer or a HexaChloroDisilane-SiN (HCD-SiN) layer is formed on the surface of a transistor as an etching stopper layer. After removing part of the etching stopper layer, a gate protection film is formed on the surface of the gate electrode of a transistor. Due to the high etching selectivity of the gate protection film to the dielectric layer, the gate protection film effectively prevents the gate electrode of a transistor from being etched in the contact-etching process. In addition, the gate protection film has a low dielectric constant thereby reducing the parasitic capacitance of a bit line formed by the self-aligned contact forming method according to the present invention.