Abstract: Provided is a method for measurement of a change in environment at a sensor. The sensor has: a first layer formed of a piezoelectric material; a second layer formed adjacent the first layer and acoustically coupled with the first layer; and electrodes disposed to apply a driving signal to the first layer to generate bulk acoustic waves. The temperature coefficient of frequency of the first layer is different to that of the second layer. In the method, a first layer resonant frequency associated with the first layer and a combination resonant frequency associated with a combination of the first and second layers are detected. A shift in one or both of the first layer resonant frequency and the combination resonant frequency is detected. A portion of the shift caused by a temperature change at the sensor is identified. Another portion of the shift caused by an environmental change at the sensor other than the temperature change is identified.

Abstract: Provided is a method for measurement of a change in environment at a sensor. The sensor has: a first layer formed of a piezoelectric material; a second layer formed adjacent the first layer and acoustically coupled with the first layer; and electrodes disposed to apply a driving signal to the first layer to generate bulk acoustic waves. The temperature coefficient of frequency of the first layer is different to that of the second layer. In the method, a first layer resonant frequency associated with the first layer and a combination resonant frequency associated with a combination of the first and second layers are detected. A shift in one or both of the first layer resonant frequency and the combination resonant frequency is detected. A portion of the shift caused by a temperature change at the sensor is identified. Another portion of the shift caused by an environmental change at the sensor other than the temperature change is identified.

Abstract: Provided is a micro fluidic transportation device capable of controlling discontinuous transportation of micro droplets using surface acoustic wave (SAW), and a method for manufacturing the same. The micro fluidic transportation device which includes: a substrate; a piezoelectric layer formed on the substrate; an inter digitated transducer (IDT) electrode formed on the piezoelectric layer for energy conversion by generating a surface acoustic wave (SAW); and a fluid passage formed on the piezoelectric thin layer.

Abstract: A method of manufacturing a micromechanical element wherein the method comprises the steps of providing a layer of base material, applying at least one at least partly sacrificial layer of an etchable material, patterning the at least partly sacrificial layer, to define at least a portion of the shape of the element, applying at least one structural layer of a mechanical material, patterning the structural layer to form at least a portion of the element, and removing at least partly the patterned at least partly sacrificial layer to release partly free the element. The mechanical material is selected from the group of conductive materials.

Abstract: Provided is a micro fluidic transportation device capable of controlling discontinuous transportation of micro droplets using surface acoustic wave (SAW), and a method for manufacturing the same. The micro fluidic transportation device which includes: a substrate; a piezoelectric layer formed on the substrate; an inter digitated transducer (IDT) electrode formed on the piezoelectric layer for energy conversion by generating a surface acoustic wave (SAW); and a fluid passage formed on the piezoelectric thin layer.

Abstract: A method of manufacturing a micromechanical element wherein the method comprises the steps of providing a layer of base material, applying at least one at least partly sacrificial layer of an etchable material, patterning the at least partly sacrificial layer, to define at least a portion of the shape of the element, applying at least one structural layer of a mechanical material, patterning the structural layer to form at least a portion of the element, and removing at least partly the patterned at least partly sacrificial layer to release partly free the element. The mechanical material is selected from the group of conductive materials.