A nanoelectronic system comprised of n microelectromechanical or nanoelectromechanical devices arranged on a connection support to electrically connect the n devices, each device with an interaction area, at least one mechanical anchor and a first terminal, a second terminal and a third terminal, the relative arrangement of the first, second and third terminals, the anchor area and the interaction area being identical or similar for the n sensors, the first terminal of each device being intended to recover a signal emitted by each representative device of the interaction area state. At least part of the devices are arranged in such a way that the geometric location of the first terminal of one of the adjacent devices is identical to the geometric location of the first terminal of said other adjacent device, the first terminals being coincident.

A substrate assembly and a method of bonding substrates are disclosed. The method includes steps of: providing two substrate; subjecting a connecting surface of each of the substrates to surface-modifying treatment to form surface-modified region respectively on each of the connecting surfaces; contacting the substrates in such a manner that the substrates are connected with each other through a physical interaction between the surface-modified regions; and laser irradiating and melting a portion of each of the connecting surfaces to form a respective bonding region, and solidifying the melted bonding regions of the substrates to bond the substrates together.

A substrate structure for a micro electro mechanical system (MEMS) device, a semiconductor structure and a method for fabricating the same are provided. In various embodiments, the substrate structure for the MEMS device includes a substrate, the MEMS device, and an anti-stiction layer. The MEMS device is over the substrate. The anti-stiction layer is on a surface of the MEMS device, and includes amorphous carbon, polytetrafluoroethene, hafnium oxide, tantalum oxide, zirconium oxide, or a combination thereof.

Method and systems that provide improved handling and/or culturing and/or assaying of cells, chemically active beads, or similar materials in microfluidic systems and microfluidic culture arrays.

The present disclosure provides a packaging method, including: providing a first semiconductor substrate; forming a bonding region on the first semiconductor substrate, wherein the bonding region of the first semiconductor substrate includes a first bonding metal layer and a second bonding metal layer; providing a second semiconductor substrate having a bonding region, wherein the bonding region of the second semiconductor substrate includes a third bonding layer; and bonding the first semiconductor substrate to the second semiconductor substrate by bringing the bonding region of the first semiconductor substrate in contact with the bonding region of the second semiconductor substrate; wherein the first and third bonding metal layers include copper (Cu), and the second bonding metal layer includes Tin (Sn). An associated packaging structure is also disclosed.

Disclosed is a flexible electronic circuit substrate that includes a device that is fabricated from layers of the flexible electronic circuit substrate as part of construction of the flexible electronic circuit substrate. Such devices could be functional units such as micro electro mechanical devices (MEMS) devices such as micro-accelerometer sensor elements, micro flow sensors, micro pressure sensors, etc.

A method for producing a MEMS device comprises forming a semiconductor layer stack, the semiconductor layer stack comprising at least a first monocrystalline semiconductor layer, a second monocrystalline semiconductor layer and a third monocrystalline semiconductor layer, the second monocrystalline semiconductor layer formed between the first and third monocrystalline semiconductor layers. A semiconductor material of the second monocrystalline semiconductor layer is different from semiconductor materials of the first and third monocrystalline semiconductor layers. After forming the semiconductor layer stack, at least a portion of each of the first and third monocrystalline semiconductor layers is concurrently etched.

Micromachined ultrasonic transducers integrated with complementary metal oxide semiconductor (CMOS) substrates are described, as well as methods of fabricating such devices. Fabrication may involve two separate wafer bonding steps. Wafer bonding may be used to fabricate sealed cavities in a substrate. Wafer bonding may also be used to bond the substrate to another substrate, such as a CMOS wafer. At least the second wafer bonding may be performed at a low temperature.

In a method of inferring ambient atmospheric temperature, an acoustic signal is emitted from a speaker. A first sample of the acoustic signal is captured with a first microphone spaced a first distance from the speaker. A second sample of the acoustic signal is captured with a second microphone spaced a second distance from the speaker. The second distance is greater than the first distance, and a difference between the first distance and the second distance is a known third distance. A time delay in the acoustic signal is determined between the first sample and the second sample. An ambient temperature of the atmosphere through which the acoustic signal traveled is inferred based on a relationship between the time delay and temperature for the acoustic signal over the third distance.

An ultrathin free-standing solid state membrane, including an etched well on a glass wafer, and a layer of SiX deposited on a backside of the etched well on the glass wafer.