A chip package includes a semiconductor substrate and a metal layer. The semiconductor substrate has an opening and a sidewall surrounding the opening, in which an upper portion of the sidewall is a concave surface. The semiconductor substrate is made of a material including silicon. The metal layer is located on the semiconductor substrate. The metal layer has plural through holes above the opening to define a MEMS (Microelectromechanical system) structure, in which the metal layer is made of a material including aluminum.

A method of forming an infrared detector includes defining an optical window in a cover substrate. Defining the optical window includes forming a multilayer interference filter or a periodic diffraction grating on an upper surface of the optical window and a periodic diffraction grating on the lower surface of the optical window. The method also includes performing anodic bonding of a spacer onto the cover substrate, transferring the cover substrate provided onto a base substrate, and hermetically bonding the spacer onto the base substrate.

In a method of generating a microelectromechanical system, MEMS, device, a MEMS substrate including a movable element is provided. A glass cover member including a glass cover is formed by hot embossing. The glass cover member is bonded to the MEMS substrate so as to hermetically seal by the glass cover a cavity in which the movable element is arranged.

A MEMS device includes an electrical distribution substrate and a spacer ring extending upward therefrom. An actuator stator is positioned above the electrical distribution substrate and within the spacer ring. An outer frame extends from a floor of the actuator stator. An actuator rotor is suspended above the floor. A sensor is supported by the actuator rotor. A conductive stack is positioned above the spacer ring. A wire electrically connects the sensor to the conductive stack. A plurality of vias extending through the spacer ring and to the electrical distribution substrate, thereby allowing electrical communication between the sensor and the electrical distribution substrate while enabling vertical displacement of the sensor and actuator rotor.

A method for manufacturing an optical microelectromechanical device, includes forming, in a first wafer of semiconductor material having a first surface and a second surface, a suspended mirror structure, a fixed structure surrounding the suspended mirror structure, elastic supporting elements extending between the fixed structure and the suspended mirror structure, and an actuation structure coupled to the suspended mirror structure. The method continues with forming, in a second wafer, a chamber delimited by a bottom wall having a through opening, and bonding the second wafer to the first surface of the first wafer and bonding a third wafer to the second surface of the first wafer so that the chamber overlies the actuation structure, and the through opening is aligned to the suspended mirror structure, thus forming a device composite wafer. The device composite wafer is diced to form an optical microelectromechanical device.

A device includes one or more layers of a microelectromechanical system (MEMS) structure and a dielectric stack over the one or more layers. The dielectric stack includes a first dielectric layer having a first index of refraction, and a second dielectric layer having a second index of refraction different than the first index of refraction.