Abstract: Methods and associated structures of forming a microelectronic device are described. Those methods may comprise forming a conductive layer on a single crystal ferroelectric material, patterning the conductive layer to form contacts, attaching a portion of a circuit on the patterned conductive layer, lapping the single crystal ferroelectric material to a thickness of about 1 to about 10 microns and then etching the single crystal to a thickness below about 25 nm.

Abstract: Methods and associated structures of forming a microelectronic device are described. Those methods may forming a conductive layer on a substrate, patterning the conductive layer, forming at least one nanodot on the patterned conductive layer, and forming a thin film ferroelectric material on the at least one nanodot.

Abstract: A method and system for forming FBAR filters for different frequency bands with film stacks of different thicknesses, where at least some layers of different thicknesses are formed substantially at the same time, during a process operation are described herein.

Abstract: A process comprising, in a vacuum, depositing a bottom electrode layer and a piezoelectric layer over a cavity in a substrate, the cavity being filled with a sacrificial material, patterning and etching the piezoelectric layer and the bottom electrode layer to expose one or more edges of the bottom electrode layer and the piezoelectric layer, treating some or all of the one or more edges to prevent electrical contact between the bottom electrode layer and a top electrode layer, and depositing and etching the top electrode layer.

Abstract: According to embodiments of the present invention, vibration sensor array includes at least two microelectromechanical systems (MEMS) vibration sensors formed on a substrate. The vibration element of the first vibration sensor is a different type than the vibration element of the second vibration sensor. For example, the at least two different vibration elements may be selected from a cantilever beam, a bridge beam, a membrane, and/or an annular diaphragm.

Abstract: Multiple FBARs may be manufactured on a single wafer and later diced. Ideally, all devices formed in a wafer would have the same resonance frequency. However, due to manufacturing variances, the frequency response of the FBAR devices may vary slightly across the wafer. An RF map may be created to determine zones over the wafer where FBARs in that zone all vary from a target frequency by a similar degree. A tuning layer may be deposited over the wafer. Lithographically patterned features to the tuning layer based on the zones identified by the RF map may be used to correct the FBARs to a target resonance frequency with the FBARs still intact on the wafer.

Abstract: The specification discloses embodiments of an apparatus comprising a film bulk acoustic resonator (FBAR) filter comprising a piezoelectric membrane having a portion thereof sandwiched between a first electrode and a second electrode, the piezoelectric membrane being suspended from at least two edges thereof, and a heat transfer layer placed on the piezoelectric membrane surrounding, but not in contact with, the first electrode. Also disclosed are embodiments of a process comprising sandwiching a portion of the piezoelectric membrane between a first electrode and a second electrode, suspending a piezoelectric membrane from at least two edges thereof, and placing a heat transfer layer on the piezoelectric membrane surrounding, but not in contact with, the first electrode. Other embodiments are disclosed and claimed.

Abstract: The specification discloses embodiments of an apparatus comprising a film bulk acoustic resonator (FBAR) filter comprising a piezoelectric membrane having a portion thereof sandwiched between a first electrode and a second electrode, the piezoelectric membrane being suspended from at least two edges thereof, and a heat transfer layer placed on the piezoelectric membrane surrounding, but not in contact with, the first electrode. Also disclosed are embodiments of a process comprising sandwiching a portion of the piezoelectric membrane between a first electrode and a second electrode, suspending a piezoelectric membrane from at least two edges thereof, and placing a heat transfer layer on the piezoelectric membrane surrounding, but not in contact with, the first electrode. Other embodiments are disclosed and claimed.

Abstract: An FBAR device may be chemically functionalized by depositing an interactive layer so that targeted chemicals are preferentially adsorbed. Such miniaturized chemical sensors may be combined with wireless network technology. For example, a chemical sensor may be integrated in a cell phone, PDA, a watch, or a car with wireless connection and GPS. Since such devices are widely populated, a national sensor network may be established. Consequently, a national toxicity map can be generated in real time. Detailed chemical information may be obtained, such as if a chemical is released by a source fixed on ground or by a moving object, or if is spread by explosives or by wind and so on.

Abstract: A method for forming a device on a substrate of <110> silicon includes forming a first conductive layer onto the substrate, and forming a piezoelectric layer on the first portion of a first conductive layer. A second electrode is formed on the piezoelectric layer, and a backside portion of the substrate under the piezoelectric layer and the first conductive layer is removed using a crystal orientated dependent etch.

Abstract: A film bulk acoustic resonator is formed on a substrate having a major surface. The film bulk acoustic resonator includes an elongated stack. The elongated stack includes a layer of piezoelectric material positioned between a first conductive layer deposited on a first surface of the layer of piezoelectric material, and a second conductive layer deposited on a second surface of the layer of piezoelectric material. The elongated stack is positioned substantially perpendicular with respect to the major surface of the substrate. The first and second conductive layers are placed on the layer of piezoelectric material substantially simultaneously and in one processing step. The major surface of the substrate is in a horizontal plane and the stack of the film bulk acoustic resonator is in a substantially vertical plane. The resonator structure formed may be used either as a resonator or a filter.

Abstract: A process comprising, in a vacuum, depositing a bottom electrode layer and a piezoelectric layer over a cavity in a substrate, the cavity being filled with a sacrificial material, patterning and etching the piezoelectric layer and the bottom electrode layer to expose one or more edges of the bottom electrode layer and the piezoelectric layer, treating some or all of the one or more edges to prevent electrical contact between the bottom electrode layer and a top electrode layer, and depositing and etching the top electrode layer.

Abstract: An apparatus comprising a substrate and an array of vibration sensors formed on the substrate, the array comprising two or more vibration sensors, wherein each vibration sensor in the array has a different noise floor and a different operational frequency range than any of the other vibration sensors in the array. A process comprising forming an array of vibration sensors on a substrate, the array comprising two or more vibration sensors, wherein each of the two or more vibration sensors in the array has a different noise floor and a different operational frequency range than any of the other vibration sensors in the array. Other embodiments are disclosed and claimed.

Abstract: An apparatus, according to one aspect, may include a chromatograph and a bulk acoustic resonator. The chromatograph may include a channel that is defined at least partially in a monolithic substrate. The channel may have an inlet to receive a sample and an outlet. A chromatography material may be included in the channel. The bulk acoustic resonator may have a first electrode and a second electrode that has a chemically functionalized surface. The chemically functionalized surface may be included in a chamber that is defined at least partially in the monolithic substrate and that is coupled with the outlet of the channel. Methods of making and using such apparatus, and systems including such apparatus, are also disclosed.

Abstract: A film bulk acoustic resonator is formed on a substrate. The film bulk acoustic resonator includes a layer of piezoelectric material having a first surface proximate the substrate, and a second surface distal from the substrate. The first conductive layer deposited on the first surface of the piezoelectric material includes a first portion having a surface on a different plane than a surface associated with a second portion.

Abstract: An apparatus and method to provide a tapered electrode in an acoustic resonator. A piezoelectric (PZ) layer, such as Aluminum Nitride (AlN), is formed over a bottom electrode having a tapered end. A top electrode is positioned on the PZ layer. The tapered end of the bottom electrode creates a mild topography to the under layer of the PZ material to prevent cracking in the PZ layer. The tapered end also decreases acoustic losses in the acoustic resonator because the PZ grains are highly oriented. In one embodiment, the acoustic resonator is a film bulk acoustic resonator (FBAR).

Abstract: A film bulk acoustic resonator filter may be formed with a plurality of interconnected series and shunt film bulk acoustic resonators formed on the same membrane. Each of the film bulk acoustic resonators may be formed from a common lower conductive layer which is defined to form the bottom electrode of each film bulk acoustic resonator. A common top conductive layer may be defined to form each top electrode of each film bulk acoustic resonator. A common piezoelectric film layer, that may or may not be patterned, forms a continuous or discontinuous film.

Abstract: Systems and methods for detecting the presence of biomolecules in a sample using biosensors that incorporate resonators which have functionalized surfaces for reacting with target biomolecules. In one embodiment, a device includes a piezoelectric resonator having a functionalized surface configured to react with target molecules, thereby changing the mass and/or charge of the resonator which consequently changes the frequency response of the resonator. The resonator's frequency response after exposure to a sample is compared to a reference, such as the frequency response before exposure to the sample, a stored baseline frequency response or a control resonator's frequency response.

Abstract: Systems and methods for detecting the presence of biomolecules in a sample using biosensors that incorporate resonators which have functionalized surfaces for reacting with target biomolecules. In one embodiment, a device includes a piezoelectric resonator having a functionalized surface configured to react with target molecules, thereby changing the mass and/or charge of the resonator which consequently changes the frequency response of the resonator. The resonator's frequency response after exposure to a sample is compared to a reference, such as the frequency response before exposure to the sample, a stored baseline frequency response or a control resonator's frequency response.

Abstract: A component having a FBAR filter with FBARs, and on-chip inductor are described herein.