A semiconductor package structure includes an electronic device having an exposed region adjacent to a first surface, a dam surrounding the exposed region of the semiconductor die and disposed on the first surface, the dam having a top surface away from the first surface, an encapsulant encapsulating the first surface of the electronic device, exposing the exposed region of the electronic device. A surface of the dam is retracted from a top surface of the encapsulant. A method for manufacturing the semiconductor package structure is also provided.

A method for manufacturing a protective layer for protecting an intermediate structural layer against etching with hydrofluoric acid, the intermediate structural layer being made of a material that can be etched or damaged by hydrofluoric acid, the method comprising the steps of: forming a first layer of aluminum oxide, by atomic layer deposition, on the intermediate structural layer; performing a thermal crystallization process on the first layer of aluminum oxide, forming a first intermediate protective layer; forming a second layer of aluminum oxide, by atomic layer deposition, above the first intermediate protective layer; and performing a thermal crystallization process on the second layer of aluminum oxide, forming a second intermediate protective layer and thereby completing the formation of the protective layer. The method for forming the protective layer can be used, for example, during the manufacturing steps of an inertial sensor such as a gyroscope or an accelerometer.

A method for manufacturing a structure comprises a) providing a donor substrate comprising front and rear faces; b) providing a support substrate; c) forming an intermediate layer on the front face of the donor substrate or on the support substrate; d) assembling the donor and support substrates with the intermediate layer therebetween; e) thinning the rear face of the donor substrate to form a useful layer of a useful thickness having a first face disposed on the intermediate layer and a second free face; and wherein the donor substrate comprises a buried stop layer and a fine active layer having a first thickness less than the useful thickness, between the front face of the donor substrate and the stop layer; and after step e), removing, in first regions of the structure, a thick active layer delimited by the second free face of the useful layer and the stop layer.

A MEMS microphone and a manufacturing method thereof. The method comprises: sequentially forming a first isolation layer, a diaphragm, and a second isolation layer on a substrate; sequentially forming a first protective layer, a backplate electrode, and a second protective layer on the second isolation layer; forming a release hole penetrating through the first protective layer, the backplate electrode, and the second protective layer; forming an acoustic cavity penetrating through the substrate; releasing the diaphragm through the acoustic cavity and the release hole; and forming a groove on a surface of the first isolation layer, wherein the diaphragm conformally covers the surface of the first isolation layer, thereby forming a spring structure at a position of the groove.

A semiconductor device comprises a structured metal layer. The structured metal layer lies above a semiconductor substrate. In addition, a thickness of the structured metal layer is more than 100 nm. Furthermore, the semiconductor device comprises a covering layer. The covering layer lies adjacent to at least one part of a front side of the structured metal layer and adjacent to a side wall of the structured metal layer. In addition, the covering layer comprises amorphous silicon carbide.

A method includes forming an etch stop layer over a first side of a device wafer. The method also includes forming a polysilicon layer over the etch stop layer. A handle wafer is fusion bonded to the first side of the device wafer. A eutectic bond layer is formed on a second side of the device wafer. A micro-electro-mechanical system (MEMS) features are etched into the second side of the device wafer to expose the etch stop layer. The exposed etch stop layer is removed to expose the polysilicon layer. The exposed polysilicon layer is removed to expose a cavity formed between the handle wafer and the device wafer.

Provided is a gas sensor including a substrate, a first membrane disposed on the substrate, a heating structure disposed on the first membrane, a second membrane disposed on the heating structure, a sensing electrode disposed on the second membrane, and a sensing material structure disposed on the sensing electrode. Here, the substrate provides an isolation space defined by a recessed surface obtained as a portion of a top surface of the substrate is spaced downward from a bottom surface of the first membrane, and the first membrane provides a first membrane etching hole that vertically extends to connect a top surface and the bottom surface of the first membrane and is connected with the isolation space. Also, the first membrane etching hole has a diameter of about 3 μm to about 20 μm.

A micro electromechanical system (MEMS) includes a substrate, a semiconductor device and a protection wall. The substrate has a surface. The semiconductor device is disposed on the surface. The protection wall has a poly-silicon layer surrounding the semiconductor device and connecting to the surface.

A Micro-Electro-Mechanical Systems (MEMS) device includes a substrate, an electronic circuit on the substrate, an electrode electrically connected to the electronic circuit, a movable element that is controlled by applying a voltage between the electrode and the movable element, an insulating layer between the electrode and the electronic circuit, and an etch stop layer. The insulating layer has a via electrically connecting the electrode and the electronic circuit, and the etch stop layer is made of at least one of Aluminum nitride or Aluminum oxide. The etch stop layer may cover the electrode and the electronic circuit, or the electrode may be mounted on the etch stop layer, electrically connected to the electronic circuit through the etch stop layer by the via.

A method for manufacturing a microelectromechanical systems (MEMS) structure with sacrificial supports to prevent stiction is provided. A first etch is performed into an upper surface of a carrier substrate to form a sacrificial support in a cavity. A thermal oxidation process is performed to oxidize the sacrificial support, and to form an oxide layer lining the upper surface and including the oxidized sacrificial support. A MEMS substrate is bonded to the carrier substrate over the carrier substrate and through the oxide layer. A second etch is performed into the MEMS substrate to form a movable mass overlying the cavity and supported by the oxidized sacrificial support. A third etch is performed into the oxide layer to laterally etch the oxidized sacrificial support and to remove the oxidized sacrificial support. A MEMS structure with anti-stiction bumps is also provided.