Patent application number | Description | Published |
20110156528 | MICRO ACTUATOR, MICRO ACTUATOR SYSTEM, AND METHOD FOR FABRICATING MICRO ACTUATOR - A micro actuator system includes a micro actuator and a light beam generator. The micro actuator includes a substrate, a cantilever beam, and a carbon nano-tube layer. The cantilever beam has a connection portion connected to the substrate, and the carbon nano-tube layer is disposed on the cantilever beam in a spray deposition technique. When the light beam generator generates a light beam for irradiating the carbon nano-tube layer on the connection portion of the cantilever beam, the carbon nano-tube layer drives the cantilever beam to be deformed towards a first direction. | 06-30-2011 |
20110193262 | Method for forming a microstructure on a polymeric substrate - A method for forming a microstructure on a polymeric substrate includes: providing a master mold formed with a micro-feature thereon, the micro-feature having a base portion and a plurality of protrusion portions protruding from the base portion, each of the protrusion portions having a tapered anisotropic shape, including a free end distal from the base portion, and being spaced apart from an adjacent one of the protrusion portions, a distance between the free ends of two adjacent ones of the protrusion portions being not greater than 40 nm; and impressing the free end of each of the protrusion portions of the micro-feature into the polymeric substrate at an elevated temperature T | 08-11-2011 |
20110241260 | METHOD FOR FORMING A MOLECULARLY IMPRINTED POLYMER BIOSENSOR - A method for forming a molecularly imprinted polymer biosensor includes: (a) preparing a reaction solution including an imprinting molecule, a functional monomer, an initiator, and a crosslinking agent; (b) disposing the reaction solution in a space between upper and lower substrates each of which is made of a light-transmissible material; (c) disposing on the upper substrate a photomask having a patterned hole; (d) irradiating the reaction solution through the patterned hole of the photomask and the upper substrate so that the reaction solution undergoes polymerization to form a polymer between the upper and lower substrates; (e) removing the upper substrate after the polymer is formed on the lower substrate; and (f) extracting the imprinting molecule from the polymer so that a patterned molecularly imprinted polymer film is formed on the lower substrate. | 10-06-2011 |
20110247707 | MICROFLUIDIC CHIP DEVICE AND METHOD OF MAKING THE SAME - A microfluidic chip device includes a substrate layer and a microfluidic layer. The substrate layer is made from a shape memory polymer, and includes a transformative portion that can change in volume when changing in shape between a memory shape and a temporary shape. The microfluidic layer is laminated with the substrate layer and has a microchannel that is in fluid communication with the transformative portion. The transformative portion produces a fluid driving pressure within the microchannel when changing between the memory shape and the temporary shape. A method of making the microfluidic chip device is also disclosed. | 10-13-2011 |
20130180852 | ELECTRODE, SENSOR CHIP USING THE SAME AND METHOD OF MAKING THE SAME - A working electrode includes a conducting layer, a carbon nanotube layer electrophoretically deposited on the conducting layer; and a gold nanoparticle layer sputter-deposited on the carbon nanotube layer. A sensor chip having the working electrode and a method of fabricating the working electrode are also disclosed. | 07-18-2013 |
20140117584 | INKJET PRINTING METHOD FOR FORMING A CONTINUOUS THREE-DIMENSIONAL STRUCTURE - An inkjet printing method for forming a continuous three-dimensional structure is disclosed. A pre-patterned temporary structure is formed on a substrate for defining a filling groove on the substrate. An inkjet printing process is performed for filling the ink droplets into the filling groove. The ink droplets cover the filling groove and contact the surface of the temporary structure and the substrate at the same time. A self-aligned effect is formed by a composition of the gravity of the ink droplets, a surface tension between the ink droplets and the temporary structure, and a surface tension between the ink droplets and the substrate. When the ink droplets are solidified, a standalone continuous three-dimensional structure is formed by removing the temporary structure. The geometry of the continuous three-dimensional structure can be defined by the temporary structure; therefore a small track width of the solidified ink droplets can be obtained. | 05-01-2014 |
20150188032 | ELECTRIC OUTPUT PROMOTING AND FABRICATING METHOD OF PIEZOELECTRIC/CONDUCTIVE HYBRID POLYMER THIN FILM - A method of fabricating a piezoelectric/conductive hybrid polymer thin film is provided, which is promoting an electric output of a piezoelectric polymer and includes: a mixing step including: forming a piezoelectric solution by dissolving a PVDF-TrFE in an active solvent; forming a conductive solution by dissolving a PEDOT:PSS in a water; and forming a piezoelectric/conductive hybrid polymer solution by mixing the piezoelectric solution and the conductive solution; a filming step, wherein the piezoelectric/conductive hybrid polymer solution is heated, thus the piezoelectric/conductive hybrid polymer thin film is formed; and an anneal step, wherein the piezoelectric/conductive hybrid polymer thin film is recrystallized and a nano-sized protruding structure is formed on a surface of the piezoelectric/conductive hybrid polymer thin film. | 07-02-2015 |
20150202625 | METHOD FOR FABRICATING MICROFLUIDIC STRUCTURES - A method for fabricating microfluidic structures is provided. The method includes: a belt is provided and an adhesion layer is formed on at least one surface of the belt; the belt is cut for forming a first microfluidic channel thereon, wherein the first microfluidic channel has an accommodating space; a second microfluidic channel is provided, wherein a line-width of the second microfluidic channel is smaller than a line-width of the first microfluidic channel; the second microfluidic channel is disposed in the accommodating space of the first microfluidic channel; and a substrate is adhered to the belt via the adhesion layer. | 07-23-2015 |