Abstract: Systems and methods for noncontact ablation of tissues or materials in/on the body using an ablation catheter that has a directional ablation unit. The ablation unit has a set of individual transducer (e.g., ultrasound) elements that are movably positioned. A position adjustment element (a deformer) is movable with respect to the ultrasonic transducer to alter the positions of the individual transducer elements and thereby alter the directions in which the transducer elements emit ultrasonic energy. In one embodiment, the ablation catheter is a lumen catheter through which a positioning/measurement catheter can be inserted. The luminal ablation catheter is inserted through the skin and into the body via conventional methods. The ablation and positioning catheters can be used to make electrical measurements with respect to the surrounding tissue, and the ablation catheter can be used to emit energy in a desired direction and/or pattern to ablate target tissue.

Abstract: A tool unit applied to ultrasonic machining, includes an amplitude transformer, a machining head and a connecting portion. The machining head has a micron-sized array structure. With the connecting portion, the amplitude transformer and the machining head are assembled together and the connecting portion has a change in shape. The machining head includes a substrate and at least one diamond layer. An upper surface of substrate touches the amplitude transformer or the connecting portion. And the diamond layer is disposed on an lower surface of substrate. The material of the substrate is selected from a group of a steel material with thermal expansion coefficient ranged from 10.70×10?6K?1 to 17.30×10?6K?1, tungsten carbide and combination thereof. The material of the diamond layer is selected from a group of a diamond material with thermal expansion coefficient ranged from 1.00×10?6K?1 to 2.50×10?6K?1, a polycrystalline diamond, a diamond sintered body and combination thereof.

Abstract: An ultrasonic micron precision molding apparatus includes: an ultrasonic generating module, a tool and an amplitude transformer. The ultrasonic generating module provides ultrasonic frequency vibration. The tool is disposed below the ultrasonic generating module, and has a micron-level precision structure. The amplitude transformer is disposed between the ultrasonic generating module and the tool and has a first section and a second section, the first section is disposed at the junction of the amplitude transformer and the tool, and the distance between the second section and the tool is longer than the distance between the first section and the tool, wherein the width of the first section is greater than the width of the second section.

Abstract: A gas sensor comprises a layered structure with an ionic conductive film and a high gas-permeability interlayer film, a first catalyst electrode and a second catalyst electrode, a conductivity promotion structure, a high-k layer and a current detecting unit. The ionic conductive film includes a material with ionic conductivity ranging from 0.02 to 1000 S/cm. The first catalyst electrode and second catalyst electrode are located on the layered structure and spaced by a predetermined distance for ionizing a gas and reducing the ionized gas, respectively. The conductivity promotion structure includes a material with electronic conductivity ranging from 10?5 to 105 S/cm, and provides wanted electrons for a reduction reaction. The high-k layer is interposed between the conductivity promotion structure and layered structure. The current detecting unit is coupled to the first catalyst electrode and second catalyst electrode to sense a detecting current with respect to the ionized gas.

Abstract: An ultrasonic micron precision molding apparatus includes: an ultrasonic generating module, a tool and an amplitude transformer. The ultrasonic generating module provides ultrasonic frequency vibration. The tool is disposed below the ultrasonic generating module, and has a micron-level precision structure. The amplitude transformer is disposed between the ultrasonic generating module and the tool and has a first section and a second section, the first section is disposed at the junction of the amplitude transformer and the tool, and the distance between the second section and the tool is longer than the distance between the first section and the tool, wherein the width of the first section is greater than the width of the second section.

Abstract: A tool unit applied to ultrasonic machining, includes an amplitude transformer, a machining head and a connecting portion. The machining head has a micron-sized array structure. With the connecting portion, the amplitude transformer and the machining head are assembled together and the connecting portion has a change in shape. The machining head includes a substrate and at least one diamond layer. An upper surface of substrate touches the amplitude transformer or the connecting portion. And the diamond layer is disposed on an lower surface of substrate. The material of the substrate is selected from a group of a steel material with thermal expansion coefficient ranged from 10.70×10?6K?1 to 17.30×10?6K?1 , tungsten carbide and combination thereof. The material of the diamond layer is selected from a group of a diamond material with thermal expansion coefficient ranged from 1.00×10?6K?1 to 2.50×10?6K?1, a polycrystalline diamond, a diamond sintered body and combination thereof.

Abstract: An electrochemistry apparatus comprises a supporting body and a reaction layer for generating electromotive force. The supporting body is made of a first material. The reaction layer covers the surface of the supporting body and comprises an ion conductive layer, a first film electrode and a second film electrode. The first and the second film electrodes are separately formed on two opposite surfaces of the ion conductive layer. The ion conductive layer is made of a second material having a thermal expansion coefficient approximating to the thermal expansion coefficient of the first material. The second material has an ionic conductivity greater than the ionic conductivity of the first material. The first material has a toughness greater than the second material. The electrochemistry apparatus employs the supporting body with improved toughness and the ion conductive layer with improved ion conductivity, so as to increase sensitivity and thermal shock resistance.

Abstract: A fuel cell includes a substrate layer, a first electrode, a second electrode, a first chamber layer and a second chamber layer, and all of which are integrally formed by co-firing. The substrate layer includes a first surface and a second surface opposite to the second surface, and the first electrode, the second electrode are formed on the first and second surfaces, respectively. The first chamber layer, disposed on the first electrode, includes a first flow passage and a first fuel chamber connected thereto, and a first gas passes the first flow passage, enters the first fuel chamber and contacts the first electrode. The second chamber, disposed on the second electrode, includes a second flow passage and a second fuel chamber connected thereto, and a second gas passes the second flow passage, enters the second fuel chamber and contacts the second electrode.

Abstract: A gas sensor is provided. The gas sensor includes a post, an ion conductive layer, a first sensing portion and a second sensing portion. The post includes a first end, a second end, a side surface and a groove, wherein the groove is formed on the side surface of the post, and an opening is formed on the first end connecting with the groove. The ion conductive layer is formed on the side surface of the post, including a first surface and a second surface, wherein the first surface is opposite to the second surface, and the ion conductive layer and the groove compose a chamber. The first sensing portion is formed on the first surface. The second sensing portion is formed on the second surface corresponding to the first sensing portion, wherein the first sensing portion is located in the chamber.

Abstract: An electrochemistry apparatus comprises a supporting body and a reaction layer for generating electromotive force. The supporting body is made of a first material. The reaction layer covers the surface of the supporting body and comprises an ion conductive layer, a first film electrode and a second film electrode. The first and the second film electrodes are separately formed on two opposite surfaces of the ion conductive layer. The ion conductive layer is made of a second material having a thermal expansion coefficient approximating to the thermal expansion coefficient of the first material. The second material has an ionic conductivity greater than the ionic conductivity of the first material. The first material has a toughness greater than the second material. The electrochemistry apparatus employs the supporting body with improved toughness and the ion conductive layer with improved ion conductivity, so as to increase sensitivity and thermal shock resistance.

Abstract: A fuel cell includes a substrate layer, a first electrode, a second electrode, a first chamber layer and a second chamber layer, and all of which are integrally formed by co-firing. The substrate layer includes a first surface and a second surface opposite to the second surface, and the first electrode, the second electrode are formed on the first and second surfaces, respectively. The first chamber layer, disposed on the first electrode, includes a first flow passage and a first fuel chamber connected thereto, and a first gas passes the first flow passage, enters the first fuel chamber and contacts the first electrode. The second chamber, disposed on the second electrode, includes a second flow passage and a second fuel chamber connected thereto, and a second gas passes the second flow passage, enters the second fuel chamber and contacts the second electrode.

Abstract: A gas sensor is provided. The gas sensor includes a post, an ion conductive layer, a first sensing portion and a second sensing portion. The post includes a first end, a second end, a side surface and a groove, wherein the groove is formed on the side surface of the post, and an opening is formed on the first end connecting with the groove. The ion conductive layer is formed on the side surface of the post, including a first surface and a second surface, wherein the first surface is opposite to the second surface, and the ion conductive layer and the groove compose a chamber. The first sensing portion is formed on the first surface. The second sensing portion is formed on the second surface corresponding to the first sensing portion, wherein the first sensing portion is located in the chamber.

Abstract: A gas sensor is provided. The gas sensor includes a substrate, a first electrode, a second electrode, a power source and a current meter. The substrate includes a planar surface, wherein the substrate is made of ion-conductive material, proton-conductive material or electron-conductive material. The first electrode is formed on the planar surface. The second electrode is formed on the planar surface, wherein a gap is formed between the first electrode and the second electrode. The power source is electrically connected to the first electrode and the second electrode, wherein the power source provides a voltage to the first electrode and the second electrode. The current meter is electrically connected to the first electrode and tie second electrode to measure a limit current passing the first electrode and the second electrode.