Aspects of the present disclosure describe systems, methods, and structures that enable a compact, UHV ion trap system that can operate at temperatures above cryogenic temperatures. Ion trap systems in accordance with the present disclosure are surface treated and sealed while held in a UHV environment, where disparate components are joined via UHV seals, such as weld joints, compressible metal flanges, and UHV-compatible solder joints. As a result, no cryogenic pump is required, thereby enabling an extremely small-volume system.

The present invention relates to a sensor arrangement, to a corresponding method of assembling such a sensor arrangement, and to a sensor system. The sensor arrangement comprises at least one transducer element for monitoring at least one measurand and generating an electrical output signal correlated with the at least one measurand; and a sensor substrate comprising the transducer element. The sensor substrate is mountable on a circuit carrier in a way that a media channel penetrating the circuit carrier allows access of the at least one measurand to the transducer element. The circuit carrier has an electrically conductive solderable first sealing pattern which surrounds the media channel at least partly and which is aligned with a solderable second sealing pattern arranged on the sensor substrate, so that a soldered sealing connection, which at least partly surrounds the media channel, is formed between the first sealing pattern and the second sealing pattern.

A micromechanical apparatus and a corresponding production method are described. The micromechanical apparatus encompasses a base substrate having a front side and a rear side; and a cap substrate, at least one surrounding trench having non-flat side walls being embodied in the front side of the base substrate; the front side of the base substrate and the trench being coated with at least one metal layer; the non-flat side walls of the trench being covered nonconformingly with the metal so that they do not form an electrical current path in a direction extending perpendicularly to the front side; and a closure, in particular a seal-glass closure, being embodied in the region of the trench between the base substrate and the cap substrate.

A physical quantity sensor includes a sensor element (acceleration sensor element) and a substrate (package) to which the sensor element is attached using a bonding material (resin adhesive), in which, when an elastic modulus of the bonding material is e, 2.0 GPa<e<7.8 GPa is satisfied.

A Micro-Electro-Mechanical System (MEMS) device includes a substrate, a packaging component provided on the substrate and a MEMS component provided inside the packaging component and on the substrate. The device further includes a sealing component. The sealing component is provided on the substrate and/or the packaging component, for preventing an external small molecule from contacting with the MEMS component.

A method for producing a micromechanical component having a substrate and a cap that are connected to each other and that enclose a first cavity, where a first pressure prevails inside the first cavity and a first gas mixture having a first chemical composition is enclosed within the first cavity, includes, in a first method step, developing in the substrate or cap an access opening connecting the first cavity to an environment of the micromechanical component, in a second method step, setting the first pressure and/or the first chemical composition in the first cavity, in a third method step, sealing the access opening using a laser by introduction of energy or heat into an absorbing part of the substrate or the cap, and, in a fourth method step, performing a thermal treatment of the substrate or the cap, thereby reducing temperature gradients in the substrate or in the cap.

A method for setting a pressure in a cavity formed with the aid of a substrate and a substrate cap, a microelectromechanical system being situated in the cavity, the substrate including a main extension plane. The method includes the following steps: in a first step a clearance is created in the substrate cap, the clearance connecting the cavity to the surroundings, a first clearance end of the clearance being formed on a first surface of the substrate cap that faces away from the cavity, a second clearance end of the clearance being formed on a cavity-side second surface of the substrate cap, the first clearance end and the second clearance end being situated at a distance from one another at least in a first direction which is parallel to the main extension plane; in a second step, after the first step, the clearance is sealed.

In an embodiment A package includes a casing having an opening and enclosing a cavity, a die accommodated in the cavity and a membrane attached to the casing, the membrane being air-permeable, covering and sealing the opening, wherein the membrane is configured to allow only a lateral gas flow, and wherein a blocking member is configured to block a vertical gas flow through the membrane into the cavity, the blocking member tightly covering a surface of the membrane at least in an area comprising the opening.

A bonded structure can include a first element having a first conductive interface feature and a second element having a second conductive interface feature. An integrated device can be coupled to or formed with the first element or the second element. The first conductive interface feature can be directly bonded to the second conductive interface feature to define an interface structure. The interface structure can be disposed about the integrated device in an at least partially annular profile to connect the first and second elements.

A package encapsulating electronic components of one or more Micro-Electro-Mechanical Systems (MEMS) devices has hermetic seal that enables the use of a frame with rough surface. That is, the frame surrounds the components and is affixed to a surface of the substrate with a frame adhering layer. A cover is affixed to the frame with a cover adhering layer. Each of the frame adhering layer and the cover adhering layer comprises a solder layer between metallic adhesion layers. The solder layer comprises reflowed solder balls. The package enables direct contact of a substrate with a heat sink.