A method for providing a semiconductor layer arrangement on a substrate which comprises providing a semiconductor layer arrangement having a functional layer and a semiconductor substrate layer, attaching the semiconductor layer arrangement to a glass substrate layer such that the functional layer is arranged between the glass substrate layer and the semiconductor substrate layer, and removing the semiconductor substrate layer at least partially such that the glass substrate layer substitutes the semiconductor substrate layer as the substrate of the semiconductor layer arrangement.

Micro-Electro-Mechanical System (MEMS) structures, methods of manufacture and design structures are disclosed. The method includes forming a Micro-Electro-Mechanical System (MEMS) beam structure by venting both tungsten material and silicon material above and below the MEMS beam to form an upper cavity above the MEMS beam and a lower cavity structure below the MEMS beam.

A method of forming an ultrasonic transducer device involves depositing a first layer on a substrate, depositing a second layer on the first layer, patterning the second layer at a region corresponding to a location of a transducer cavity, depositing a third layer that refills regions created by patterning the second layer, planarizing the third layer to a top surface of the second layer, removing the second layer, conformally depositing a fourth layer over the first layer and the third layer, defining the transducer cavity in a support layer formed over the fourth layer; and bonding a membrane to the support layer.

An ultrasonic transducer device includes a patterned film stack disposed on first regions of a substrate, the patterned film stack including a metal electrode layer and a bottom cavity layer formed on the metal electrode layer. The ultrasonic transducer device further includes a planarized insulation layer disposed on second regions of the substrate layer, a cavity formed in a membrane support layer and a CMP stop layer, the CMP stop layer including a top layer of the patterned film stack and the membrane support layer formed over the patterned film stack and the planarized insulation layer. The ultrasonic transducer device also includes a membrane bonded to the membrane support layer. The CMP stop layer underlies portions of the membrane support layer but not the cavity.

An ultrasound transducer device includes an electrode, a membrane, and vias. The membrane is separated from the electrode by a cavity between the membrane and the electrode. The vias electrically connect the electrode to a substrate disposed on an opposite side of the electrode from a side facing the membrane. The vias are disposed in the ultrasound transducer device such that greater than 50% of the vias overlap with the cavity in a plan view.

An ultrasound transducer device includes an electrode, a membrane, and vias. The membrane is separated from the electrode by a cavity between the membrane and the electrode. The vias electrically connect the electrode to a substrate disposed on an opposite side of the electrode from a side facing the membrane. The vias are disposed in the ultrasound transducer device such that greater than 50% of the vias overlap with the cavity in a plan view.

A membrane is formed through processes including depositing a first piezoelectrical layer, depositing a first electrode layer over the first piezoelectrical layer, patterning the first electrode layer to form a first electrode, depositing a second piezoelectrical layer over the first electrode, depositing a second electrode layer over the second piezoelectrical layer, patterning the second electrode layer to form a second electrode, and depositing a third piezoelectrical layer over the second electrode. The third piezoelectrical layer, the second piezoelectrical layer, and the first piezoelectrical layer are etched to form a through-hole. The through-hole is laterally spaced apart from the first electrode and the second electrode. A first contact plug and a second contact plug are then formed to electrically connect to the first electrode and the second electrode, respectively.

A method may include etching a number of holes into a carrier wafer layer to form a plurality of filters in the carrier wafer layer, patterning a chamber layer over a first side of the carrier wafer layer to form chambers above each filter formed in the carrier wafer layer, forming a layer over the chamber layer, grinding a second side of the carrier wafer layer to expose the number of holes etched into the carrier wafer layer, and bonding a molded substrate to the carrier wafer layer opposite the chamber layer.

Various embodiments of the present disclosure are directed towards a microelectromechanical systems (MEMS) structure including a composite spring. A first substrate underlies a second substrate. A third substrate overlies the second substrate. The first, second, and third substrates at least partially define a cavity. The second substrate comprises a moveable mass in the cavity and between the first and third substrates. The composite spring extends from a peripheral region of the second substrate to the moveable mass. The composite spring is configured to suspend the moveable mass in the cavity. The composite spring includes a first spring layer comprising a first crystal orientation, and a second spring layer comprising a second crystal orientation different than the first crystal orientation.

A method of forming a capacitive micromachined ultrasonic transducer (CMUT) device includes bonding a CMUT substrate to a silicon on insulator (SOI) substrate. The CMUT substrate has a first thickness and the SOI substrate includes a handle, a buried oxide layer, and a device layer. At least one of the CMUT substrate or the SOI substrate includes a patterned dielectric layer. The device layer is bonded to the patterned dielectric layer to form a plurality of sealed cavities and the device layer forms a diaphragm of the plurality of cavities. The method further includes reducing the first thickness of the CMUT substrate to a second thickness and forming a plurality of through-silicon vias from a second surface of the CMUT substrate opposite the first surface.